EP2933914B1 - Power converter circuit and air conditioner - Google Patents

Power converter circuit and air conditioner Download PDF

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Publication number
EP2933914B1
EP2933914B1 EP15001646.7A EP15001646A EP2933914B1 EP 2933914 B1 EP2933914 B1 EP 2933914B1 EP 15001646 A EP15001646 A EP 15001646A EP 2933914 B1 EP2933914 B1 EP 2933914B1
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EP
European Patent Office
Prior art keywords
converter circuit
switching elements
circuit
power converter
current
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EP15001646.7A
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German (de)
French (fr)
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EP2933914A3 (en
EP2933914A2 (en
Inventor
Shinichi Ishizeki
Toshiaki Satou
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Daikin Industries Ltd
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Daikin Industries Ltd
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    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02MAPPARATUS FOR CONVERSION BETWEEN AC AND AC, BETWEEN AC AND DC, OR BETWEEN DC AND DC, AND FOR USE WITH MAINS OR SIMILAR POWER SUPPLY SYSTEMS; CONVERSION OF DC OR AC INPUT POWER INTO SURGE OUTPUT POWER; CONTROL OR REGULATION THEREOF
    • H02M7/00Conversion of ac power input into dc power output; Conversion of dc power input into ac power output
    • H02M7/02Conversion of ac power input into dc power output without possibility of reversal
    • H02M7/04Conversion of ac power input into dc power output without possibility of reversal by static converters
    • H02M7/12Conversion of ac power input into dc power output without possibility of reversal by static converters using discharge tubes with control electrode or semiconductor devices with control electrode
    • H02M7/125Avoiding or suppressing excessive transient voltages or currents
    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02MAPPARATUS FOR CONVERSION BETWEEN AC AND AC, BETWEEN AC AND DC, OR BETWEEN DC AND DC, AND FOR USE WITH MAINS OR SIMILAR POWER SUPPLY SYSTEMS; CONVERSION OF DC OR AC INPUT POWER INTO SURGE OUTPUT POWER; CONTROL OR REGULATION THEREOF
    • H02M1/00Details of apparatus for conversion
    • H02M1/12Arrangements for reducing harmonics from ac input or output

Definitions

  • the present invention relates to a power converter circuit and an air conditioner having the power converter circuit.
  • a large electromagnetic relay is conventionally used in a power converter circuit comprising a converter circuit and the like.
  • the electromagnetic relay is used as a power switch for ensuring safety when the circuit is not in use or as a power switch for cutting off and protecting a power supply when an abnormality occurs.
  • a power switch is provided on each of three input lines from a three-phase AC power supply to a current-type converter (refer to paragraph 0037, Fig. 1 , and the like).
  • Patent Document 1 Japanese Patent Application Laid-open No. 2009-95149
  • a moving contact mechanically opens or closes. Therefore, welding-induced stiction or degradation of the moving contact may potentially cause reliability of the power converter circuit to decline (problem 1).
  • electromagnetic noise occurs due to contact bounce when the moving contact opens or closes. Propagation of the electromagnetic noise to a low current circuit such as a control circuit of the power converter circuit may potentially cause the circuit to malfunction.
  • a connection wire to a commercial power supply is shared by a converter circuit and a low current circuit is connected to a power supply branching from the connection wire, the low curcurrent circuit is significantly affected (problem 2).
  • the electromagnetic relay when an electromagnetic relay is used in a power switch, the electromagnetic relay must be large. Therefore, substrate size of the power supply circuit increases (problem 3).
  • EP 2 249 471 A1 relates to a direct AC power converter.
  • a control section controls a current-source converter while a switch is conducting, to render conducting a pair of a high-arm side transistor and a low-arm side transistor which are connected to any one of input lines, performs voltage doubler rectification on a voltage between an neutral phase input line on which a resistor is provided and any one of the input lines to serve for charging of clamp capacitors.
  • the switch connected to the neutral point of the three-phase-system and the middle point between the capacitors via the resistor is switched on, and in order to cause the upper and lower arms to enter a conductive state only in the R phase, the transistors Srp and Srn to enter a conductive state and the transistors Ssp, Ssn, Stp and Stn to enter a non-conductive state.
  • An object of the present invention is to provide a power converter circuit and an air conditioner which are capable of solving the problems described above.
  • the present invention provides a power converter circuit according to claim 1.
  • the switching elements function as power switches. Therefore, a large electromagnetic relay as a power switch can be eliminated from an input unit of a converter circuit. As a result, the following effects (1) to (3) can be obtained. (1) Since there is no longer a risk of welding-induced stiction or degrading of the moving contact of the electromagnetic relay previously used as the power switch, reliability of the converter circuit can be improved. (2) Electromagnetic noise generated when the moving contact opens and closes can be prevented from propagating to a low current circuit such as a control circuit of the power converter circuit and, in particular, to a low current circuit which shares a connection wire to a commercial power supply with the converter circuit and which is connected to a power supply branching from the connection wire. (3) A circuit board can be downsized.
  • a large electromagnetic relay as a power switch can be eliminated from the power converter circuit. Therefore, according to the present invention, the reliability of the converter circuit can be improved, electromagnetic noise generated by the opening and closing of the electromagnetic relay can be prevented from propagating to a low current circuit such as a control circuit of the power converter circuit and, in particular, to a low current circuit which shares a connection wire to a commercial power supply with the converter circuit and which is connected to a power supply branching from the connection wire, and the circuit board can be downsized.
  • Fig. 1 is a block diagram showing a schematic configuration of a power converter circuit 2A in a power supply circuit included in an air conditioner 1A according to a first example.
  • the air conditioner 1A comprises a refrigerant circuit (not shown) to which a compressor, a heat source-side heat exchanger, an expansion valve, and a utilization-side heat exchanger (all not shown) are connected through piping. Due to driving by the compressor, the air conditioner 1A circulates a refrigerant in the refrigerant circuit to execute a refrigeration cycle.
  • the air conditioner 1A comprises a high pressure sensor. When high pressure of the refrigeration cycle rises abnormally, the high pressure sensor detects the abnormal rise of the high pressure and outputs a high pressure abnormality signal to the power converter circuit 2A.
  • the power converter circuit 2A stops driving of the compressor. As a result, the refrigeration cycle stops.
  • the high pressure sensor is not limited to any system as long as the high pressure sensor has a function of outputting the fact that a high pressure state exists.
  • the high pressure sensor will be described as a high-pressure switch 400 which outputs a presence/absence of a high pressure abnormality in states of ON (a high pressure abnormality detection signal is outputted upon detection of high pressure abnormality)/OFF (a high pressure abnormality detection signal is not outputted).
  • a motor M is connected to the power converter circuit 2A.
  • the compressor included in the air conditioner 1A is driven by the motor M.
  • the power converter circuit 2A comprises a converter circuit 10A, an inverter circuit 20, a smoothing circuit 30A, a current-limiting circuit 40, a control unit 300A, a coil L, and shunt resistors R2 and R3.
  • the control unit 300A comprises a CPU (Central Processing Unit), an EEPROM (Electrically Erasable Programmable Read Only Memory), and the like.
  • the CPU executes a control program stored in the EEPROM in advance in order to control operations of the converter circuit 10A, the inverter circuit 20, and the like.
  • the converter circuit 10A is connected to a three-phase four-wire AC power supply E3 via input lines Lr, Ls, Lt (first to third input lines) corresponding to respective phases of R, S, T and a neutral line Ln.
  • the converter circuit 10A is connected to the inverter circuit 20 and to a smoothing capacitor C that constitutes the smoothing circuit 30A via a positive-side DC power line L1 and a negative-side DC power line L2.
  • the converter circuit 10A comprises upper arm-side switching elements Trp, Ttp and lower arm-side switching elements Trn, Ttn.
  • the upper arm-side switching elements Trp, Ttp are respectively provided between the input lines Lr, Lt and the positive-side DC power line L1.
  • the upper arm-side switching elements Trp, Ttp are, for example, IGBTs (Insulated Gate Bipolar Transistors).
  • the lower arm-side switching elements Trn, Ttn are respectively provided between the negative-side DC power line L2 and the input lines Lr, Lt.
  • the lower arm-side switching elements Trn, Ttn are, for example, IGBTs.
  • pairs (a pair made up of Trp and Trn and a pair made up of Ttp and Ttn) of the switching elements are respectively provided on upper and lower arms of the R phase and the T phase in the present example, pairs of the switching elements need only be respectively provided on any two phases among the three phases of R, S, T. In other words, a total of two pairs of the switching elements need only be provided.
  • Anodes of diodes Drp, Dtp, Drn, Dtn are respectively connected to the emitters of the upper arm-side switching elements Trp, Ttp and the lower arm-side switching elements Trn, Ttn. Respective collectors of the upper arm-side switching elements Trp, Ttp are connected to the input lines Lr, Lt. Respective collectors of the lower arm-side switching elements Trn, Ttn are connected to the negative-side DC power line L2. Respective cathodes of the diodes Drp, Dtp are connected to the positive-side DC power line L1. Respective cathodes of the diodes Drn, Dtn are connected to the input lines Lr, Lt. In addition, a diode Dsp is provided on the upper arm of the S phase. A diode Dsn is provided on the lower arm of the S phase.
  • the upper arm-side switching elements Trp, Ttp, the lower arm-side switching elements Trn, Ttn, and the diodes Drp, Dtp, Drn, Dtn are connected as described above, the upper arm-side switching elements Trp, Ttp make a current pathway conductive in only one direction from the input lines Lr, Lt to the positive-side DC power line L1 in a conductive state.
  • the lower arm-side switching elements Trn, Ttn make a current pathway conductive in only one direction from the negative-side DC power line L2 to the input lines Lr, Lt in a conductive state.
  • the upper arm-side switching elements Trp, Ttp and the lower arm-side switching elements Trn, Ttn are not limited to switching elements which make current pathways conductive in only the directions described above and may instead be bidirectional energizing elements that enable energization in two directions including toward the side of the positive-side DC power line L1 and toward the side of the negative-side DC power line L2.
  • the control unit 300A generates, as appropriate, a predetermined energization angle signal or PWM (Pulse Width Modulation) signal that is synchronized with a power supply phase as a drive signal.
  • the control unit 300A outputs the drive signal to respective gates of the upper arm-side switching elements Trp, Ttp and the lower arm-side switching elements Trn, Ttn to appropriately switch the switching elements. Switching control of the upper and lower arm-side switching elements (the upper arm-side switching elements and the lower arm-side switching elements) of the converter circuit 10A will be described in detail later.
  • the smoothing capacitor C of the smoothing circuit 30A is, for example, an electrolytic capacitor.
  • the smoothing capacitor C is connected to a load side of the converter circuit 10A and supplies power to the inverter circuit 20 as a voltage supply.
  • the smoothing capacitor C smoothes power outputted by the converter circuit 10A by temporally storing and then releasing the power outputted by the converter circuit 10A.
  • two capacitors that are not high breakdown voltage capacitors are provided in series. By providing two capacitors connected in series in this manner, breakdown voltage characteristics that are comparable to using one high breakdown voltage capacitor as the smoothing capacitor can be achieved.
  • by connecting the current-limiting circuit at a connection point between the two capacitors provided in series low-voltage charging can be performed.
  • the inverter circuit 20 is a voltage-type inverter circuit.
  • the inverter circuit 20 is connected to the motor M via output lines Lu, Lv, Lw corresponding to respective phases of U, V, W.
  • the inverter circuit 20 is connected to the converter circuit 10A and the smoothing capacitor C via the positive-side DC power line L1 and the negative-side DC power line L2.
  • the inverter circuit 20 comprises upper arm-side switching elements Tup, Tvp, Twp, lower arm-side switching elements Tun, Tvn, Twn, and an inverter gate drive IC 200.
  • the upper arm-side switching elements Tup, Tvp, Twp are respectively provided between the positive-side DC power line L1 and the output lines Lu, Lv, Lw.
  • the upper arm-side switching elements Tup, Tvp, Twp are, for example, IGBTs.
  • the lower arm-side switching elements Tun, Tvn, Twn are respectively provided between the output lines Lu, Lv, Lw and the negative-side DC power line L2.
  • the lower arm-side switching elements Tun, Tvn, Twn are, for example, IGBTs.
  • Anodes of diodes Dup, Dvp, Dwp, Dun, Dvn, Dwn are respectively connected to emitters of the upper arm-side switching elements Tup, Tvp, Twp and the lower arm-side switching elements Tun, Tvn, Twn.
  • Cathodes of the diodes Dup, Dvp, Dwp, Dun, Dvn, Dwn are respectively connected to collectors of the upper arm-side switching elements Tup, Tvp, Twp and the lower arm-side switching elements Tun, Tvn, Twn.
  • diodes are connected in inverse-parallel to each of the upper and lower arm-side switching elements of the inverter circuit 20.
  • the inverter gate drive IC 200 receives a control signal from the control unit 300A and appropriately generates a PWM signal in accordance with the control signal as a drive signal.
  • the inverter gate drive IC 200 outputs the drive signal to respective gates of the upper arm-side switching elements Tup, Tvp, Twp and the lower arm-side switching elements Tun, Tvn, Twn to appropriately open or close the switching elements.
  • the inverter circuit 20 appropriately switches each of the upper and lower arm-side switching elements, converts DC power outputted from the smoothing capacitor C into AC power with a voltage and a frequency corresponding to a drive state of the motor, and outputs the AC power to windings of respective phases of the motor M.
  • the current-limiting circuit 40 is a circuit provided in order to prevent an inrush current from flowing to the smoothing capacitor C at the start of energization of the power converter circuit 2A.
  • an inrush current refers to a spike-like large current which flows when charge is not stored in the smoothing capacitor C.
  • the current-limiting circuit 40 is provided on the neutral line Ln.
  • the current-limiting circuit 40 is constructed by connecting a current-limiting resistor R1 and a current-limiting switch 84C in series.
  • the current-limiting switch is not limited to any system as long as the current-limiting switch has a function of reliably connecting and cutting off the current-limiting circuit.
  • an electromagnetic relay will be described as the current-limiting switch.
  • the current-limiting switch will be described as being a current-limiting relay (84C).
  • the control unit 300A closes the current-limiting relay 84C at the start of energization of the power converter circuit 2A. Accordingly, a current that flows in the current-limiting circuit is suppressed by the current-limiting resistor R1 and flows to the smoothing capacitor C. As a result, charges gradually accumulate in the smoothing capacitor C.
  • the control unit 300A performs control involving opening the current-limiting relay 84C after the start of energization of the power converter circuit 2A and upon a lapse of a predetermined period of time in which an inrush current can be suppressed.
  • a timing at which the control unit 300A opens the current-limiting relay 84C is not limited to a timing based on the lapse of a predetermined period of time as described above.
  • a wide variety of timings can be applied as long as an inrush current can be suppressed such as a point where voltage of the smoothing capacitor C is charged to or above a predetermined value or a point where an inrush current value during current-limiting falls to or below a predetermined value (this similarly applies to the respective embodiments below).
  • the coil L is provided between the converter circuit 10A and the smoothing circuit 30A on the positive-side DC power line L1.
  • the coil L is a reactor provided in order to smooth current from the converter circuit 10A.
  • the shunt resistor R2 is provided between the converter circuit 10A and the smoothing capacitor C on the negative-side DC power line L2.
  • the shunt resistor R3 is provided between the smoothing capacitor C and the inverter circuit 20 on the negative-side DC power line L2.
  • the shunt resistor R2 and the shunt resistor R3 respectively measure a value of a current flowing in the converter circuit 10A and a value of a current flowing in the inverter circuit 20.
  • the shunt resistor R2 and the shunt resistor R3 are used to provide control or protection of the converter and the inverter.
  • an indoor unit (not shown) included in the air conditioner 1 that is provided inside an air-conditioned room is generally provided with an indoor remote controller (not shown) which is capable of communicating with a control unit (not shown) of the air conditioner.
  • a control unit not shown
  • the control unit itself acts as the control unit 300A which issues commands regarding operation states of the power converter circuit.
  • communication is carried out between a separately-provided control unit 300A and the control unit described above to issue commands regarding operation states of the power converter circuit.
  • Fig. 2 is a time chart showing behavior of each pair of upper and lower arm-side switching elements of the R phase and the T phase and the like during a period from start of energization of the power converter circuit 2A to stop of charging of the smoothing capacitor C.
  • (A) represents a state of the indoor remote controller
  • (C) represents a state of the current-limiting relay 84C
  • (D) represents a state of the pair of upper and lower arm-side switching elements Trp and Trn of the R phase connected to the input line Lr
  • (E) represents a state of the pair of upper and lower arm-side switching elements Ttp and Ttn of the T phase connected to the input line Lt
  • (F) represents a state of the respective upper and lower arm-side switching elements of the inverter circuit 20
  • (G) represents a state of the motor M.
  • the control unit 300A closes the current-limiting relay 84C. Accordingly, energization of the power converter circuit 2A is started. At the same time, the control unit 300A fixes the respective pairs of upper and lower arm-side switching elements Trp, Trn and Ttp, Ttn of the R phase and the T phase to a non-conductive state. Accordingly, accumulation of charges in the smoothing capacitor C is started (time t 2 ). In other words, the control unit 300A performs control in which only the S phase not provided with switching elements is placed in a conductive state. As a result, the control unit 300A prevents an inrush current from flowing to the smoothing capacitor C by ensuring that currents always flow through the current-limiting resistor R1.
  • the configuration of the conductive state is not limited to the pair of upper and lower arm-side switching elements of the S phase.
  • the pair of upper and lower arm-side switching elements of any one of the phases among the respective pairs of upper and lower arm-side switching elements of the R, S, T phases may be configured so as to enter a conductive state.
  • the pair of upper and lower arm side of any one phase of the respective pairs of upper and lower arm sides of the R, T phases may be provided with diodes in a similar manner to the S phase.
  • switching elements are provided on the respective pairs of upper and lower arm sides of the other two phases.
  • the switching elements are to be subjected by the control unit 300A to control similar to the conduction/non-conduction control of the respective pairs of upper and lower arm-side switching elements Trp, Trn and Ttp, Ttn of the R phase and the T phase described earlier.
  • the control unit 300A opens the current-limiting relay 84C and, at the same time, fixes the respective pairs of upper and lower arm-side switching elements of the R phase and the T phase in a conductive state (time t 3 ).
  • the time t 3 at which the current-limiting relay 84C is opened is a time at which the control unit 300A has measured the lapse of a predetermined period of time described above (a predetermined period of time in which an inrush current can be suppressed) using a built-in timer or the like from the point at which the current-limiting relay 84C had been closed at time t 2 (from the point at which energization of the power converter circuit 2A had been started) (as described earlier, the timing at which the current-limiting relay 84C is opened is not limited to this timing control).
  • control unit 300A starts switching control of the respective upper and lower arm-side switching elements of the inverter circuit 20 (start of operation of the inverter circuit 20, time t 4 ). Accordingly, driving of the motor M is started and normal operation of the air conditioner 1A is started.
  • the control unit 300A places the respective upper and lower arm-side switching elements of the inverter circuit 20 in a non-conductive state. Accordingly, supply of power to the motor M is stopped (time t 6 ). However, since reflux of energy of motor inductance and refrigerant circulation in the refrigerant circuit do not stop immediately, the motor M stops after briefly continuing inertia operation (time t 7 ).
  • control unit 300A subsequently places the respective pairs of upper and lower arm-side switching elements Trp, Trn and Ttp, Ttn of the R phase and the T phase in a non-conductive state and discharges the capacitor C using a discharge circuit (not shown) (time tg).
  • control unit 300A need only control switching of each of the switching elements Trp, Trn, Ttp, Ttn so that the upper and lower arms of at least two phases of the three phases including the R phase, the T phase, and the S phase comprising the diodes Dsp, Dsn enter a non-conductive state.
  • Fig. 3 is a time chart showing behavior of each pair of upper and lower arm-side switching elements of the R phase and the T phase and the like during a period from start of energization of the power converter circuit 2A to stop of the motor M when the high-pressure switch 400 is activated.
  • (B) represents a state of a high pressure abnormality signal outputted when the high-pressure switch 400 is activated. Otherwise, the states represented by (A) to (G) correspond to Fig. 2 .
  • the high-pressure switch 400 When the high-pressure switch 400 detects an abnormal rise in high pressure of a refrigeration cycle and is activated, the high-pressure switch 400 outputs a high pressure abnormality signal to the control unit 300A.
  • the control unit 300A places the respective upper and lower arm-side switching elements of the inverter circuit 20 in a non-conductive state and stops the supply of power to the motor M (time t 6 ').
  • the control unit 300A places the respective pairs of upper and lower arm-side switching elements Trp, Trn and Ttp, Ttn of the R phase and the T phase in a non-conductive state (time t 7 ').
  • control unit 300A may control switching of each of the switching elements Trp, Trn, Ttp, Ttn so that either the upper arm-side switching elements Trp, Ttp of both the R phase and the T phase or the lower arm-side switching elements Trn, Ttn of both the R phase and the T phase enter a non-conductive state.
  • FIG. 4 A schematic configuration of the power converter circuit 2A' in the power supply circuit included in an air conditioner 1A' is shown in Fig. 4 .
  • the power converter circuit 2A' shares the same configuration as the power converter circuit 2A with the exception of a configuration of a converter circuit 10A' that is connected to the single-phase AC power supply E1, a configuration of a smoothing circuit 30A', and the fact that a current-limiting circuit 50 is connected between an input line L1 and the positive-side DC power line L1 instead of on the neutral line.
  • the current-limiting circuit 50 may be connected to the negative-side DC power line L2.
  • two current-limiting circuits may be provided, namely, a current-limiting circuit connected to the positive-side DC power line L1 and a current-limiting circuit connected to the negative-side DC power line L2.
  • the converter circuit 10A' is connected to the single-phase AC power supply E1 via the input line L1 corresponding to an L phase and an input line Ln corresponding to an N phase.
  • the converter circuit 10A' is connected to the inverter circuit 20 and to a smoothing capacitor C that constitutes the smoothing circuit 30A' via the positive-side DC power line L1 and the negative-side DC power line L2.
  • the converter circuit 10A' comprises an upper arm-side switching element Tip and a lower arm-side switching element Tln.
  • the upper arm-side switching element Tlp is provided between the input line L1 and the positive-side DC power line L1.
  • the upper arm-side switching element Tip is, for example, an IGBT.
  • the lower arm-side switching element Tln is provided between the negative-side DC power line L2 and the input line L1.
  • the lower arm-side switching element Tln is, for example, an IGBT.
  • a diode Dnp is provided on an upper arm of the N phase and a diode Dnn is provided on a lower arm of the N phase.
  • Anodes of diodes Dlp, Dln are respectively connected to the emitters of the upper arm-side switching element Tlp and the lower arm-side switching element Tln.
  • a collector of the upper arm-side switching element Tlp is connected to the input line L1.
  • a collector of the lower arm-side switching element Tln is connected to the negative-side DC power line L2.
  • a cathode of the diode Dlp is connected to the positive-side DC power line L1 and a cathode of the diode Dln is connected to the input line L1.
  • the upper arm-side switching element Tlp switches between conduction and non-conduction of a current pathway that flows from the input line L1 to the positive-side DC power line L1 in a conductive state
  • the lower arm-side switching element Tln switches between conduction and non-conduction of a current pathway that flows from the negative-side DC power line L2 to the input line Ln in a conductive state.
  • the smoothing circuit 30A' comprises a smoothing capacitor C.
  • the smoothing capacitor C is, for example, an electrolytic capacitor.
  • the smoothing capacitor C is connected to a load side of the converter circuit 10A' and supplies power to the inverter circuit 20 as a voltage supply. In other words, the smoothing capacitor C smoothes power outputted by the converter circuit 10A by temporally storing and then releasing the power outputted by the converter circuit 10A.
  • Control of switching of switching elements in the converter circuit 10A' and the like which is performed by the control unit 300A' included in the power converter circuit 2A' is shown in Fig. 5 and Fig. 6 .
  • Fig. 5 is a time chart showing behavior of the pair of upper and lower arm-side switching elements of the L phase and the like during a period from start of energization of the power converter circuit 2A' to stop of charging of the smoothing capacitor C.
  • (A) represents a state of the indoor remote controller
  • (C) represents a state of the current-limiting relay 84C
  • (D) represents a state of the pair of upper and lower arm-side switching elements Tlp and Tln of the L phase connected to the input line L1
  • (E) represents a state of the respective upper and lower arm-side switching elements of the inverter circuit 20
  • (F) represents a state of the motor M.
  • times t 1 to tg respectively correspond to times t 1 to t 8 in Fig. 2 .
  • Fig. 6 is a time chart showing behavior of a pair of upper and lower arm-side switching elements of the N phase and the like during a period from start of energization of the power converter circuit 2A' to stop of the motor M when the high-pressure switch 400 is activated.
  • (B) represents a state of a high pressure abnormality signal outputted when the high-pressure switch 400 is activated. Otherwise, the states represented by (A) to (F) correspond to Fig. 5 .
  • times t 1 to t 8 ' respectively correspond to times t 1 to tg' in Fig. 3 .
  • the control unit 300A' performs, on the pair of upper and lower arm-side switching elements Tlp and Tln of the L phase, control similar to the control performed by the control unit 300A on the respective pairs of upper and lower arm-side switching elements Trp, Trn and Ttp, Ttn of the R phase and the T phase in the converter circuit 10A connected to the three-phase AC power supply E3.
  • an example connected to a single-phase AC power supply as is the case of the present example or an example connected to a three-phase three-wire AC power supply to be described later adopts a configuration where the current-limiting relay 84C is constituted by a switching element capable of unidirectional energization or a configuration where the current-limiting relay 84C is constituted by a circuit that combines an electromagnetic relay and a unidirectional energizing element.
  • Adopting such a configuration enables a current to be sent unidirectionally from a power line to which the current-limiting circuit is connected to a DC power line and prevents a current from flowing in reverse from the power line side to the current-limiting circuit regardless of the phase relationship or a positive/negative relationship among the respective phases of the power line. As a result, a stable current-limiting operation can be performed with a simple circuit configuration.
  • control unit 300A' need only control the current-limiting relay (84C) and control switching of the respective elements so that the upper and lower arm-side switching elements of the L phase enter a non-conductive state.
  • a control unit 300B' of a power converter circuit 2B' shown in Fig. 7 and a control unit 300C' of a power converter circuit 2C' shown in Fig. 13 also need only perform switching control in a similar manner when stopping charging of the smoothing capacitor C (time t 8 ).
  • a large electromagnetic relay as a power switch can be eliminated from the power converter circuits 2 and 2'.
  • the following effects (1) to (3) can be obtained.
  • Noise generated when the moving contact opens and closes can be prevented from propagating to a low current circuit such as a control circuit of the power converter circuit and, in particular, to a low current circuit which shares the input lines Lr, Ls, Lt, Ll, Ln that act as connection wires to the commercial power supply E1 or E3 with the converter circuit 10A or 10A' and which is connected to a power supply branching from the input lines Lr, Ls, Lt, Ll, Ln.
  • a circuit board of the power converter circuit 2 can be downsized.
  • the respective switching elements included in the converter circuits 10A and 10A' function as power switches. Therefore, charging of the smoothing capacitor C can be stopped without having to use a large electromagnetic relay as a power switch.
  • Fig. 7 is a block diagram showing a schematic configuration of a power converter circuit 2B' in a power supply circuit included in an air conditioner 1B' according to a second example.
  • the power converter circuit 2B' that is connected to a single-phase AC power supply E1 differs from the power converter circuit 2A' in a configuration of a converter circuit 10B'.
  • upper arm-side switching elements Tlp, Tnp which are, for example, IGBTs are respectively provided between input lines Ll, Ln and the positive-side DC power line L1.
  • switching elements are not provided between the negative-side DC power line L2 and the input lines Ll, Ln.
  • wire connections of the current-limiting circuit 50 are similar to those of the power converter circuit 2A' according to the first example.
  • Anodes of diodes Dlp and Dnp are respectively connected to emitters of the upper arm-side switching elements Tlp and Tnp. Respective collectors of the upper arm-side switching elements Tlp and Tnp are connected to the input lines Ll and Ln.
  • Diodes Dln and Dnn are respectively provided on lower arms of the L phase and the N phase. Cathodes of the diodes Dln, Dnn are respectively connected to the input lines Ll, Ln, and anodes of the diodes Dln, Dnn are respectively connected to the negative-side DC power line L2.
  • the upper arm-side switching elements Tlp and Tnp make a current pathway conductive in only one direction from the input lines Ll and Ln to the positive-side DC power line L1 in a conductive state.
  • This is similar to the power converter circuit 2A' according to the first example. Since the configuration other than the converter circuit 10B' is similar to that of the power converter circuit 2A', a description thereof will be omitted.
  • the configuration of the converter circuit 10B' in the power converter circuit 2B' differs from the configuration of the converter circuit 10A' in the power converter circuit 2A'. Therefore, switching control of the switching elements in the converter circuit 10B' which is performed by the control unit 300B' in the power converter circuit 2B' differs from the switching control of the switching elements in the converter circuit 10A' which is performed by the control unit 300A' in the power converter circuit 2A'.
  • Fig. 8 is a time chart showing behavior of upper arm-side switching elements of the L phase and the N phase and the like during a period from start of energization of the power converter circuit 2B' to stop of charging of the smoothing capacitor C.
  • (A) represents a state of the indoor remote controller
  • (C) represents a state of the current-limiting relay 84C
  • (D) represents a state of the upper arm-side switching element Tlp of the L phase connected to the input line Ll
  • (E) represents a state of the upper arm-side switching element Tnp of the N phase connected to the input line Ln
  • (F) represents a state of the respective upper and lower arm-side switching elements of the inverter circuit 20
  • (G) represents a state of the motor M.
  • times t 1 to t 8 respectively correspond to times t 1 to tg in Fig. 5 .
  • the control unit 300B' closes the current-limiting relay 84C and, at the same time, fixes the upper arm-side switching elements Tlp and Tnp of the L phase and the N phase to a non-conductive state to start accumulation of charges in the smoothing capacitor C (time t 2 ).
  • the control unit 300B' opens the current-limiting relay 84C and, at the same time, fixes the upper arm-side switching elements Tlp and Tnp of the L phase and the N phase in a conductive state (time t 3 ).
  • the time t 3 at which the current-limiting relay 84C is opened is, for example, a time at which the control unit 300B' has measured the lapse of the predetermined period of time described earlier (a predetermined period of time in which an inrush current can be suppressed) using a built-in timer or the like from the point at which the current-limiting relay 84C had been closed at time t 2 (from the point at which energization of the power converter circuit 2B' had been started).
  • control unit 300B' starts switching control of the respective upper and lower arm-side switching elements of the inverter circuit 20 (time t 4 ). Accordingly, driving of the motor M is started and normal operation of the air conditioner 1B' is started.
  • the control unit 300B' places the respective upper and lower arm-side switching elements of the inverter circuit 20 in a non-conductive state and stops supply of power to the motor M (time t 6 ).
  • the motor M stops after briefly continuing inertia operation (time t 7 ).
  • the control unit 300B' places the upper arm-side switching elements Tlp and Tnp of the L phase and the N phase in a non-conductive state (time t 8 ).
  • Fig. 9 is a time chart showing behavior of upper arm-side switching elements of the L phase and the N phase and the like during a period from start of energization of the power converter circuit 2B' to stop of the motor M when the high-pressure switch 400 is activated.
  • (B) represents a state of a high pressure abnormality signal outputted when the high-pressure switch 400 is activated. Otherwise, the states represented by (A) to (G) correspond to Fig. 8 . Moreover, times t 1 to t 8' respectively correspond to times t 1 to t 8' in Fig. 6 .
  • the control unit 300B' places the respective upper and lower arm-side switching elements of the inverter circuit 20 in a non-conductive state and stops the supply of power to the motor M (time t 6 ').
  • the control unit 300B' places upper arm-side switching elements Tlp and Tnp of an L phase and the N phase in a non-conductive state (time t 7 ').
  • the fact that air conditioning had stopped due to a high pressure abnormality is displayed on, for example, a display unit included in the indoor remote controller.
  • the user having confirmed the display turns off the indoor remote controller and stops the operation of the air conditioner 1B' (time t 8 ').
  • a similar effect to the configuration according to the first example can also be produced by the configuration according to the second example described earlier.
  • the lower arm-side element of the N phase may be fixed to a conductive state in the power converter circuit 2B'.
  • the pair of upper and lower arm-side elements of the L phase and the upper arm-side element of the N phase act as switching elements that are switchable between conduction and non-conduction.
  • a diode or the like is used as the lower arm-side element of the N phase.
  • control unit 300B' need only control switching of the respective elements so that the pair of upper and lower arm-side switching elements of the L phase and the upper arm-side element of the N phase remain in a non-conductive state and the current-limiting relay (84C) enters a non-conductive state.
  • Fig. 10 is a block diagram showing a schematic configuration of a power converter circuit 2C in a power supply circuit included in an air conditioner 1C according to a first embodiment of the present invention.
  • the power converter circuit 2C differs from the power converter circuit 2A in a configuration of a converter circuit 10C.
  • the converter circuit 10C is a so-called current-type converter circuit which comprises an IGBT connected in series to a diode on all upper and lower arms of three phases.
  • the converter circuit 10C is capable of suppressing generation of power supply harmonics through, for example, PWM control.
  • the power converter circuit 2C comprises a smoothing circuit 30C similar to that of the power converter circuit 2A.
  • the smoothing capacitor C is, for example, an electrolytic capacitor.
  • the power converter circuit 2C has a similar configuration to the power converter circuit 2A in that the smoothing capacitor C is connected to a load side of the converter circuit 10C, the smoothing capacitor C supplies power to the inverter circuit 20 as a voltage supply, two capacitors that are not high breakdown voltage capacitors are provided in series to constitute the smoothing capacitor C, and the like.
  • the converter circuit 10C comprises upper arm-side switching elements Trp, Tsp, Ttp, lower arm-side switching elements Trn, Tsn, Ttn, and a converter gate drive IC 100.
  • the upper arm-side switching elements Trp, Tsp, Ttp are respectively provided between input lines Lr, Ls, Lt and the positive-side DC power line L1.
  • the upper arm-side switching elements Trp, Tsp, Ttp are, for example, IGBTs.
  • the lower arm-side switching elements Trn, Tsn, Ttn are respectively provided between the negative-side DC power line L2 and the input lines Lr, Ls, Lt.
  • the lower arm-side switching elements Trn, Tsn, Ttn are, for example, IGBTs.
  • Anodes of diodes Drp, Dsp, Dtp, Drn, Dsn, Dtn are respectively connected to emitters of the upper arm-side switching elements Trp, Tsp, Ttp and the lower arm-side switching elements Trn, Tsn, Ttn.
  • Respective collectors of the upper arm-side switching elements Trp, Tsp, Ttp are connected to the input lines Lr, Ls, Lt.
  • Respective collectors of the lower arm-side switching elements Trn, Tsn, Ttn are connected to the negative-side DC power line L2.
  • Respective cathodes of the diodes Drp, Dsp, Dtp are connected to the positive-side DC power line L1
  • respective cathodes of the diodes Drn, Dsn, Dtn are connected to the input lines Lr, Ls, Lt.
  • the upper arm-side switching elements Trp, Tsp, Ttp, the lower arm-side switching elements Trn, Tsn, Ttn, and the diodes Drp, Dsp, Dtp, Drn, Dsn, Dtn are connected as described above, the upper arm-side switching elements Trp, Tsp, Ttp make a current pathway conductive in only one direction from the input lines Lr, Ls, Lt to the positive-side DC power line L1 in a conductive state.
  • the lower arm-side switching elements Trn, Tsn, Ttn make a current pathway conductive in only one direction from the negative-side DC power line L2 to the input lines Lr, Ls, Lt in a conductive state.
  • the upper arm-side switching elements Trp, Tsp, Ttp and the lower arm-side switching elements Trn, Tsn, Ttn are not limited to switching elements which make current pathways conductive in only the directions described above and may instead be bidirectional energizing elements that enable energization in two directions including toward the side of the positive-side DC power line L1 and toward the side of the negative-side DC power line L2.
  • a circuit capable of bidirectional energization may be constructed by further connecting, in parallel, a circuit that performs energization only in a direction opposite to that described above. This configuration can be made comparable to a one-way energizing element by turning off a one-way energizing side.
  • the converter gate drive IC 100 receives a control signal from the control unit 300C and appropriately generates a PWM signal in accordance with the control signal as a drive signal.
  • the converter gate drive IC 100 outputs the drive signal to respective gates of the upper arm-side switching elements Trp, Tsp, Ttp and the lower arm-side switching elements Trn, Tsn, Ttn to appropriately switch the switching elements.
  • the converter circuit 10C switches the upper arm-side switching elements Trp, Tsp, Ttp and the lower arm-side switching elements Trn, Tsn, Ttn and actively performs waveform control to rectify AC power. Therefore, generation of power supply harmonics due to rectification can be suppressed compared to a converter circuit that includes an arm solely constituted by a diode bridge.
  • the configuration of the converter circuit 10C included in the power converter circuit 2C differs from the configuration of the converter circuit 10A included in the power converter circuit 2A. Therefore, switching control of the switching elements in the converter circuit 10C which is performed by the control unit 300C included in the power converter circuit 2C differs from the switching control of the switching elements in the converter circuit 10A which is performed by the control unit 300A included in the power converter circuit 2A.
  • Fig. 11 is a time chart showing behavior of respective pairs of upper and lower arm-side switching elements of the R, S, T phases and the like during a period from start of energization of the power converter circuit 2C to stop of charging of the smoothing capacitor C.
  • (A) represents a state of the indoor remote controller
  • (C) represents a state of the current-limiting relay 84C
  • (D) represents a state of the pair of upper and lower arm-side switching elements Trp and Trn of the R phase connected to the input line Lr
  • (E) represents a state of the pair of upper and lower arm-side switching elements Tsp and Tsn of the S phase connected to the input line Ls
  • (F) represents a state of the pair of upper and lower arm-side switching elements Ttp and Ttn of the T phase connected to the input line Lt
  • (G) represents a state of the respective upper and lower arm-side switching elements of the inverter circuit 20
  • (H) represents a state of the motor M.
  • times t1 to t8 respectively correspond to times t1 to t8in Fig. 2 .
  • the control unit 300C closes the current-limiting relay 84C.
  • the control unit 300C fixes only the pair of upper and lower arm-side switching elements Tsp and Tsn of the S phase in a conductive state and fixes the pairs of upper and lower arm-side switching elements Trp, Trn and Ttp, Ttn of the remaining R and T phases in a non-conductive state. Accordingly, accumulation of charges in the smoothing capacitor C is started (time t2).
  • control unit 300C performs control in which only the pair of upper and lower arm-side switching elements Tsp and Tsn of the S phase is fixed in a conductive state and only the S phase is placed in a conductive state.
  • the control unit 300C prevents an inrush current from flowing to the smoothing capacitor C by ensuring that currents always flow through the current-limiting resistor R1 in a similar manner to the power converter circuit 2A according to the first example.
  • a switching element that is fixed to a conductive state by the control unit 300C is not limited to the pair of upper and lower arm-side switching elements of the S phase.
  • control unit 300C may alternatively fix only the pair of upper and lower arm-side switching elements of any one of the phases in a conductive state and fix the pairs of upper and lower arm-side switching elements of the remaining two phases in a non-conductive state.
  • the control unit 300C opens the current-limiting relay 84C and, at the same time, fixes the upper and lower arm-side switching elements of all three phases in a conductive state (time t 3 ).
  • the time t 3 is, for example, a time at which the control unit 300C has measured the lapse of the predetermined period of time described earlier (a predetermined period of time in which an inrush current can be suppressed) using a built-in timer or the like from the point at which the current-limiting relay 84C had been closed at time t 2 (from the point at which energization of the power converter circuit 2C had been started).
  • the control unit 300C starts switching control of the respective upper and lower arm-side switching elements of the inverter circuit 20 (start of operation of the inverter circuit 20, time t 4 ). Accordingly, driving of the motor M is started. Moreover, for example, switching according to a 120-degree energization method that is synchronized with a zero cross of the power supply may be performed as control of the respective upper and lower arm-side switching elements from time t 3 to time t 4 .
  • the control unit 300C starts a synchronized operation in which the converter circuit 10C and the inverter circuit 20 are synchronized and controlled, and starts switching control of the respective upper and lower arm-side switching elements of the converter circuit 10C (start of normal operation of the air conditioner 1, time t 5 ).
  • the power converter circuit 2C according to the first embodiment differs from the power converter circuit 2A according to the first example in this regard.
  • the control unit 300C places the respective upper and lower arm-side switching elements of the inverter circuit 20 in a non-conductive state and stops supply of power to the motor M (time t 6 ).
  • the motor M stops after briefly continuing inertia operation (time t 7 ).
  • the control unit 300C places the upper and lower arm-side switching elements of all three phases R, S, T in a non-conductive state (time t 8 ).
  • the control unit 300C may control switching of each of the switching elements Trp, Trn, Tsp, Tsn, Ttp, Ttn so that the upper and lower arms of at least two phases among the three phases R, S, T enter a non-conductive state.
  • a control unit 300D of a power converter circuit 2D shown in Fig. 16 and a control unit 300E of a power converter circuit 2E shown in Fig. 17 may also perform switching control in a similar manner when stopping charging of the smoothing capacitor C (time t 8 ).
  • control unit 300C may control switching of each of the switching elements Trp, Trn, Tsp, Tsn, Ttp, Ttn so that either the upper arm-side switching elements Trp, Tsp, Ttp of all three phases R, S, T or the lower arm-side switching elements Trn, Tsn, Ttn of all three phases R, S, T enter a non-conductive state.
  • This also applies to the control performed by the control unit 300E of the power converter circuit 2E shown in Fig. 14 to be described below.
  • Fig. 12 is a time chart showing behavior of each pair of upper and lower arm-side switching elements of the R, S, T phases and the like during a period from start of energization of the power converter circuit 2C to stop of the motor M when the high-pressure switch 400 is activated.
  • (B) represents a state of a high pressure abnormality signal outputted when the high-pressure switch 400 is activated. Otherwise, the states represented by (A) to (H) correspond to Fig. 11 . Moreover, times t 1 to t 8 ' respectively correspond to times t 1 to t 8 ' in Fig. 3 .
  • the high-pressure switch 400 When the high-pressure switch 400 detects an abnormal rise in high pressure of a refrigeration cycle and is activated, the high-pressure switch 400 outputs a high pressure abnormality signal to the control unit 300C. At the same time, the control unit 300C places the respective upper and lower arm-side switching elements of the inverter circuit 20 in a non-conductive state and stops the supply of power to the motor M (time t 6 '). Subsequently, in order to stop accumulation of charges in the smoothing capacitor C, the control unit 300C places the upper and lower arm-side switching elements of all three phases R, S, T in a non-conductive state (time t 7 ').
  • the control unit 300C may control switching of each of the switching elements Trp, Trn, Tsp, Tsn, Ttp, Ttn so that the upper and lower arms of at least two phases among the three phases R, S, T enter a non-conductive state.
  • a control unit 300D of a power converter circuit 2D shown in Fig. 16 and a control unit 300E of a power converter circuit 2E shown in Fig. 17 may also perform switching control in a similar manner when stopping charging of the smoothing capacitor C (time t 8 ).
  • control unit 300C may control switching of each of the switching elements Trp, Trn, Tsp, Tsn, Ttp, Ttn so that either the upper arm-side switching elements Trp, Tsp, Ttp of all three phases R, S, T or the lower arm-side switching elements Trn, Tsn, Ttn of all three phases R, S, T enter a non-conductive state.
  • This also applies to the control performed by the control unit 300E of the power converter circuit 2E shown in Fig. 14 to be described below.
  • the fact that air conditioning had stopped due to a high pressure abnormality is displayed on, for example, a display unit included in the indoor remote controller.
  • the user having confirmed the display turns off the indoor remote controller and stops the operation of the air conditioner 1C (time t 8 ').
  • the configuration of the first embodiment can also be applied to a power converter circuit 2C' that is connected to the single-phase AC power supply E1.
  • a schematic configuration of the power converter circuit 2C' in the power supply circuit included in an air conditioner 1C' is shown in Fig. 13 .
  • the power converter circuit 2C' differs from the power converter circuit 2C in a configuration of a converter circuit 10C' connected to the single-phase AC power supply E1, in a configuration of a smoothing circuit 30C', and in wire connections of a current-limiting circuit 50.
  • the smoothing circuit 30C' shares the same configuration as the smoothing circuit 30A' shown in Fig. 4 .
  • the configuration of the power converter circuit 2C' is similar to that of the power converter circuit 2C.
  • wire connections of the current-limiting circuit 50 are similar to those of the power converter circuits 2A' and 2B' according to the first and second examples.
  • the converter circuit 10C' comprises upper arm-side switching elements Tlp, Tnp, lower arm-side switching elements Tln, Tnn, and a converter gate drive IC 100'.
  • the upper arm-side switching elements Tlp, Tnp are respectively provided between the input lines L1, Ln and the positive-side DC power line L1.
  • the upper arm-side switching elements Tlp, Tnp are, for example, IGBTs.
  • the lower arm-side switching elements Tln, Tnn are respectively provided between the negative-side DC power line L2 and the input lines L1, Ln.
  • the lower arm-side switching elements Tln, Tnn are, for example, IGBTs.
  • Anodes of diodes Dlp, Dnp, Dln, Dnn are respectively connected to emitters of the upper arm-side switching elements Tlp, Tnp and the lower arm-side switching elements Tln, Tnn.
  • Respective collectors of the upper arm-side switching elements Tlp and Tnp are connected to the input lines L1 and Ln.
  • Respective collectors of the lower arm-side switching elements Tln and Tnn are connected to the negative-side DC power line L2.
  • Respective cathodes of the diodes Dlp and Dnp are connected to the positive-side DC power line L1
  • respective cathodes of the diodes Dln and Dnn are connected to the input lines L1 and Ln.
  • the upper arm-side switching elements Tlp and Tnp make a current pathway conductive in only one direction from the input lines L1 and Ln to the positive-side DC power line L 1 in a conductive state
  • the lower arm-side switching elements Tln and Tnn make a current pathway conductive in only one direction from the negative-side DC power line L2 to the input lines L1 and Ln in a conductive state.
  • Control of opening and closing of switching elements in the converter circuit 10C' and the like which is performed by the control unit 300C' included in the power converter circuit 2C' is shown in Fig. 14 and Fig. 15 .
  • Fig. 14 is a time chart showing behavior of respective upper and lower arm-side switching elements and the like during a period from start of energization of the power converter circuit 2C' to stop of charging of the smoothing capacitor C.
  • (A) represents a state of the indoor remote controller
  • (C) represents a state of the current-limiting relay 84C
  • (D) represents a state of the upper and lower arm-side switching elements Tlp and Tln of the L phase connected to the input line L1
  • (E) represents a state of the upper and lower arm-side switching elements Tnp and Tnn of the N phase connected to the input line Ln
  • (F) represents a state of the respective upper and lower arm-side switching elements of the inverter circuit 20
  • (G) represents a state of the motor M.
  • times t 1 to t 8 respectively correspond to times t 1 to t 8 in Fig. 11 .
  • control unit 300C' may control switching of each of the switching elements Tlp, Tnp, Tln, Tnn so that either the upper arm-side switching elements Tlp, Tnp of both the L phase and the N phase or the lower arm-side switching elements Tin, Tnn of both the L phase and the N phase enter a non-conductive state.
  • Fig. 15 is a time chart showing behavior of respective upper and lower arm-side switching elements and the like during a period from start of energization of the power converter circuit 2C' to stop of the motor M when the high-pressure switch 400 is activated.
  • (B) represents a state of a high pressure abnormality signal outputted when the high-pressure switch 400 is activated. Otherwise, the states represented by (A) to (G) correspond to Fig. 14 . Moreover, times t 1 to t 8 ' respectively correspond to times t 1 to t 8 ' in Fig. 12 .
  • the control unit 300C' performs, on the upper and lower arm-side switching elements Tnp and Tnn of the N phase, control similar to that performed by the control unit 300C on the upper and lower arm-side switching elements of the S phase in the converter circuit 10C connected to the AC power supply E3.
  • the control unit 300C' performs, on the upper and lower arm-side switching elements Tlp and Tin of the L phase, control similar to that performed by the control unit 300C on the upper and lower arm-side switching elements of the R phase and the T phase in the converter circuit 10C.
  • the power converter circuit 2C' may control the respective upper and lower arm-side switching elements and the like during a period from start of energization of the power converter circuit 2C' to stop of charging of the smoothing capacitor C as depicted in the time chart shown in Fig. 19 .
  • the control unit 300C' closes the current-limiting relay 84C. Accordingly, energization of the power converter circuit 2C' is started. At the same time, the control unit 300C' fixes, to a conductive state, the lower arm-side switching element Tnn of the N phase which is a switching element of an arm on a side to which the current-limiting circuit 50 is not connected in a phase to which the current-limiting circuit 50 is not connected.
  • control unit 300C' places the remaining switching elements or, in other words, the pair of upper and lower arm-side switching elements Tlp, Tln of the L phase and the upper arm-side switching element Tnp of the N phase in a non-conductive state and starts accumulation of charges in the smoothing capacitor C (time t2).
  • the control unit 300C' prevents an inrush current from flowing to the smoothing capacitor C by ensuring that currents always flow through the current-limiting resistor R1.
  • the control unit 300C' opens the current-limiting relay 84C and, at the same time, fixes all of the switching elements of the L phase and the N phase in a conductive state (time t3).
  • the time t3 is, for example, a time at which the control unit 300C' has measured the lapse of the predetermined period of time described earlier (a predetermined period of time in which an inrush current can be suppressed) using a built-in timer or the like from the point at which the current-limiting relay 84C had been closed at time t2(from the point at which energization of the power converter circuit 2C' had been started).
  • control unit 300C' starts switching control of the respective upper and lower arm-side switching elements of the inverter circuit 20 (start of operation of the inverter circuit 20, time t4). Accordingly, driving of the motor M is started. Since subsequent control is similar to the control shown in Fig. 14 , a description thereof will be omitted.
  • the control unit 300C' may control switching of each of the switching elements Tlp, Tnp, Tln, Tnn so that the current-limiting relay (84C) and either all of the upper arm-side switching elements Tlp, Tnp of the L phase and the N phase or all of the lower arm-side switching elements Tln, Tnn of the L phase and the N phase enter a non-conductive state.
  • control unit 300C or 300C' since the control unit 300C or 300C' switches the respective upper and lower arm-side switching elements and actively performs waveform control to rectify AC power, generation of power supply harmonics due to rectification can be suppressed.
  • Other effects are similar to those produced by the first and second examples.
  • the current-limiting circuit 50 is provided between any one of input lines Lr, Ls, Lt and any one of the positive-side DC power line L1 and the negative-side DC power line L2 (in the examples shown in Fig. 16 and Fig. 17 , between the input line Lr and the positive-side DC power line L1) instead of on the neutral line Ln.
  • the upper arm-side switching elements Trp, Ttp and the lower arm-side switching elements Trn, Ttn in the power converter circuit 2D are not limited to switching elements which make current pathways conductive in only the directions described above and may instead be bidirectional energizing elements that enable energization in two directions including toward the side of the positive-side DC power line L1 and toward the side of the negative-side DC power line L2.
  • the upper arm-side switching elements Trp, Tsp, Ttp and the lower arm-side switching elements Trn, Tsn, Ttn in the power converter circuit 2E are not limited to switching elements which make current pathways conductive in only the directions described above and may instead be bidirectional energizing elements that enable energization in two directions including toward the side of the positive-side DC power line L1 and toward the side of the negative-side DC power line L2.
  • a circuit capable of bidirectional energization may be constructed by further connecting, in parallel, a circuit that performs energization only in a direction opposite to that described above. This configuration can be made comparable to a one-way energizing element by turning off a one-way energizing side.
  • a control unit 300E closes the current-limiting relay 84C and causes energization of the power converter circuit 2E to start.
  • the control unit 300E fixes the lower arm-side switching element Tsn of the S phase (a switching element of an arm to which the current-limiting circuit 50 is not connected of at least one phase among phases to which the current-limiting circuit 50 is not connected) to a conductive state, and fixes remaining switching elements or, in other words, the upper arm-side switching element Tsp of the S phase, the pair of upper and lower arm-side switching elements Trp, Trn of the R phase, and the pair of upper and lower arm-side switching elements Ttp, Ttn of the T phase in a non-conductive state to start accumulation of charges in the smoothing capacitor C (time t2).
  • the control unit 300E prevents an inrush current from flowing to the smoothing capacitor C by ensuring that currents always flow through the current-limiting resistor R1.
  • a switching element that is placed in a conductive state by the control unit 300E is not limited to the lower arm-side switching element Tsn of the S phase and may instead be the lower arm-side switching element Ttn of the T phase or both lower arm-side switching elements of the S phase and the T phase. In this case, all of the remaining switching elements are placed in a non-conductive state.
  • the control unit 300E opens the current-limiting relay 84C and, at the same time, fixes the respective pairs of upper and lower arm-side switching elements of the R phase, S phase, and the T phase in a conductive state (time t3).
  • the time t3 is a time at which the control unit 300E has measured the lapse of the predetermined period of time described earlier (a predetermined period of time in which an inrush current can be suppressed) using a built-in timer or the like from the point at which the current-limiting relay 84C had been closed at time t2(from the point at which energization of the power converter circuit 2A had been started).
  • control unit 300E starts switching control of the respective upper and lower arm-side switching elements of the inverter circuit 20 (start of operation of the inverter circuit 20, time t 4 ). Accordingly, driving of the motor M is started. Since subsequent control is similar to the control by the control unit 300C shown in Fig. 11 , a description thereof will be omitted.
  • control unit 300D included in the power converter circuit 2D shown in Fig. 16 since control of switching of upper and lower arm-side switching elements of the converter circuit 10D and the like by the control unit 300D included in the power converter circuit 2D shown in Fig. 16 is similar to the control by the control unit 300A, a description thereof will be omitted.
  • Fig. 20 shows an air conditioner IF comprising an indirect matrix converter 20A as a power converter circuit.
  • the indirect matrix converter 20A comprises a current-type converter 100A, a clamp circuit 30A', and a voltage-type inverter 20.
  • the current-type converter 100A is connected to a three-phase four-wire AC power supply E3 via input lines Lr, Ls, Lt (first to third input lines) corresponding to respective phases of R, S, T and a neutral line Ln.
  • the current-type converter 100A is connected via the positive-side DC power line L1 and the negative-side DC power line L2 to the inverter circuit 20 and the clamp circuit 30A'.
  • Switching operations of the current-type converter 100A are controlled by a control circuit 300A.
  • the current-type converter 100A comprises six sets of elements so as to correspond to upper and lower arms of the three phases, with a diode and an IGBT connected in series in each element.
  • the respective elements are an IGBT Trp and a diode Drp, an IGBT Trn and a diode Drn, an IGBT Tsp and a diode Dsp, an IGBT Tsn and a diode Dsn, an IGBT Ttp and a diode Dtp, and an IGBT Ttn and a diode Dtn.
  • An emitter of the transistor Trp is connected to an anode of the diode Drp, and a cathode of the diode Drp is connected to the DC power line L1.
  • An emitter of the transistor Tsp is connected to an anode of the diode Dsp, and a cathode of the diode Dsp is connected to the DC power line L1.
  • An emitter of the transistor Ttp is connected to an anode of the diode Dtp, and a cathode of the diode Dtp is connected to the DC power line L1.
  • An anode of the diode Drn is connected to an emitter of the transistor Trn, and a collector of the transistor Trn is connected to the DC power line L2.
  • An anode of the diode Dsn is connected to an emitter of the transistor Tsn, and a collector of the transistor Tsn is connected to the DC power line L2.
  • An anode of the diode Dtn is connected to an emitter of the transistor Ttn, and a collector of the transistor Ttn is connected to the DC power line L2.
  • a collector of the transistor Trp is connected to a cathode of the diode Drn.
  • a collector of the transistor Tsp is connected to a cathode of the diode Dsn.
  • a collector of the transistor Ttp is connected to a cathode of the diode Dtn.
  • Fig. 20 shows an example in which an anode of a diode is connected to an emitter of an IGBT in each element
  • a configuration in which a cathode of a diode is connected to a collector of an IGBT can also be adopted.
  • RB-IGBTs reverse blocking IGBTs
  • the indirect matrix converter 20A comprises the clamp circuit 30A'.
  • the clamp circuit 30A' comprises an electrolytic capacitor as the clamp capacitor C.
  • the clamp circuit 30A' functions to absorb regenerative energy of a motor.
  • Switching control of the upper and lower arm-side switching elements of the current-type converter 100A is performed in a similar manner to the switching control performed by the power converter circuit 2C which has been described with reference to Fig. 11 and Fig. 12 .
  • Fig. 21 shows an air conditioner 1G comprising an indirect matrix converter 20A' connected to the single-phase AC power supply E1.
  • the indirect matrix converter 20A' comprises a current-type converter 100A', a clamp circuit 30A", and the voltage-type inverter 20.
  • the current-type converter 100A' is connected to the single-phase AC power supply E1 via input lines L1, Ln which respectively correspond to the L and N phases.
  • the current-type converter 100A' is connected via the positive-side DC power line L1 and the negative-side DC power line L2 to the voltage-type inverter circuit 20 and the clamp circuit 30A".
  • the current-limiting circuit 50 is connected between the input line L1 and the positive-side DC power line L1.
  • Switching operations of the current-type converter 100A' are controlled by a control circuit 300A'.
  • the current-type converter 100A' comprises four sets of elements so as to correspond to upper and lower arms of the input lines L1, Ln from the single-phase AC power supply E1, with a diode and an IGBT connected in series in each element.
  • the respective elements are an IGBT Tlp and a diode Dlp, an IGBT Tln and a diode Dln, an IGBT Tnp and a diode Dnp, and an IGBT Tnn and a diode Dnn.
  • An emitter of the transistor Tlp is connected to an anode of the diode Dlp, and a cathode of the diode Dlp is connected to the DC power line L1.
  • An emitter of the transistor Tnp is connected to an anode of the diode Dnp, and a cathode of the diode Dnp is connected to the DC power line L1.
  • An anode of the diode Dln is connected to an emitter of the transistor Tln, and a collector of the transistor Tln is connected to the DC power line L2.
  • An anode of the diode Dnn is connected to an emitter of the transistor Tnn, and a collector of the transistor Tnn is connected to the DC power line L2.
  • a collector of the transistor Tlp is connected to a cathode of the diode Dln.
  • a collector of the transistor Tnp is connected to a cathode of the diode Dnn.
  • Fig. 21 shows an example in which an anode of a diode is connected to an emitter of an IGBT in each element
  • a configuration in which a cathode of a diode is connected to a collector of an IGBT can also be adopted.
  • RB-IGBTs reverse blocking IGBTs
  • the indirect matrix converter 20A' comprises the clamp circuit 30A".
  • the clamp circuit 30A" comprises an electrolytic capacitor as the clamp capacitor C.
  • the clamp circuit 30A" functions to absorb regenerative energy of a motor.
  • Switching control of the upper and lower arm-side switching elements of the current-type converter 100A' is performed in a similar manner to the switching control performed by the power converter circuit 2C' which has been described with reference to Fig. 14 and Fig. 15 .
  • the power converter circuit is a power converter circuit which is connected to a three-phase AC power supply (E3') via first to third input lines (Lr, Ls, Lt), and which is connected to a capacitor (C) via a positive-side DC power line (L1) and a negative-side DC power line (L2), and which is connected to at least one current-limiting circuit (50) that is provided between any one of the first to third input lines (Lr, Ls, Lt) and one of the positive-side DC power line (L1) and the negative-side DC power line (L2) and that includes an opening/closing switch (84C) and a current-limiting resistor (R1).
  • E3' three-phase AC power supply
  • Lr, Ls, Lt first to third input lines
  • L1 positive-side DC power line
  • L2 negative-side DC power line
  • R1 current-limiting resistor
  • the power converter circuit comprises: a switching element (Trp) that is provided on an arm on a side to which the current-limiting circuit (50) is connected of a phase to which the current-limiting circuit (50) is connected and that makes a current pathway between the first to third input lines (Lr, Ls, Lt) and the DC power lines (LI, L2) conductive in a conductive state; at least either switching elements (Tsp, Ttp) that are provided on arms on sides to which the current-limiting circuit is connected of two phases to which the current-limiting circuit is not connected and that make a current pathway from the first to third input lines (Lr, Ls, Lt) to the DC power lines (LI, L2) conductive in a conductive state, or switching elements (Trn, Tsn, Ttn) that are provided on an opposite-side arm in phase with the arm on which the switching element (Trp) is provided and both upper and lower arms of at least one phase among phases to which the current-limiting circuit is not connected and that make a current pathway
  • control units (300D, 300E) close the opening/closing switch (84C) until an inrush current becomes suppressible after start of energization of the power converter circuit, and control switching of each of the switching elements (Trp, Trn, Tsp, Tsn, Ttp, Ttn) so that the arm on the side to which the current-limiting circuit (50) is not connected of at least one phase among the phases to which the current-limiting circuit is not connected enters a conductive state and the remaining arms enter a non-conductive state.
  • the switching elements function as power switches. Therefore, a large electromagnetic relay as a power switch can be eliminated from an input unit of a converter circuit. As a result, the following effects (1) to (3) can be obtained.
  • Electromagnetic noise generated when the moving contact opens and closes can be prevented from propagating to a low current circuit such as a control circuit of the power converter circuit and, in particular, to a low current circuit which shares a connection wire to a commercial power supply with the converter circuit and which is connected to a power supply branching from the connection wire.
  • a circuit board can be downsized.
  • the power converter circuit is a power converter circuit which is connected to a single-phase AC power supply (E1) via two input lines (Ll, Ln) of an L phase and an N phase, and which is connected to a capacitor (C) via a positive-side DC power line (L1) and a negative-side DC power line (L2), and which is connected to at least one current-limiting circuit (50) that is provided between the input line (L1) of the L phase and the positive-side DC power line (L1) or between the input line (Ln) of the N phase and the negative-side DC power line (L2) and that includes an opening/closing switch (84C) and a current-limiting resistor (R1).
  • E1 single-phase AC power supply
  • L1 positive-side DC power line
  • L2 negative-side DC power line
  • R1 current-limiting resistor
  • the power converter circuit comprises: switching elements (Tlp) that are provided on an arm on a side to which the current-limiting circuit (50) is connected of a phase to which the current-limiting circuit (50) is connected and that make a current pathway between the input line (L1, Ln) of the L phase or the N phase and the DC power lines (L1, L2) conductive in a conductive state; switching elements (Tnp, Tln) that are provided at least on any one of an arm on a side to which the current-limiting circuit (50) is connected of a phase to which the current-limiting circuit (50) is not connected and an arm on a side to which the current-limiting circuit (50) is not connected of a phase to which the current-limiting circuit (50) is connected, that make a current pathway from the input line (L1, Ln) of the L phase or the N phase to the positive-side DC power line (L1) conductive in a conductive state when provided on an upper arm, and that make a current pathway from the negative-side DC power line (L
  • control units close the opening/closing switch (84C) until an inrush current becomes suppressible after start of energization of the power converter circuit, and control switching of each of the switching elements (Tlp, Tln, Tnp) so that the arm on the side to which the current-limiting circuit (50) is not connected of the phase to which the current-limiting circuit (50) is not connected enters a conductive state and the remaining arms enter a non-conductive state.
  • the switching elements function as power switches. Therefore, a large electromagnetic relay as a power switch can be eliminated from an input unit of a converter circuit. As a result, the following effects (1) to (3) can be obtained.
  • Electromagnetic noise generated when the moving contact opens and closes can be prevented from propagating to a low current circuit such as a control circuit of the power converter circuit and, in particular, to a low current circuit which shares a connection wire to a commercial power supply with the converter circuit and which is connected to a power supply branching from the connection wire.
  • a circuit board can be downsized.
  • the upper arm-side switching elements are elements which are provided on all of the upper arms of the three phases and which are respectively capable of making a current pathway conductive in only one direction from the first to third input lines (Lr, Ls, Lt) to the positive-side DC power line (L1) when in a closed state.
  • the lower arm-side switching elements are elements which are provided on all of the lower arms of the three phases and which are respectively capable of making a current pathway conductive in only one direction from the negative-side DC power line (L2) to the first to third input lines (Lr, Ls, Lt) when in a closed state.
  • control unit (300C) closes the opening/closing switch (84C) until an inrush current becomes suppressible after start of energization of the power converter circuit, and places one pair among the three pairs of the upper arm-side switching elements (Trp, Tsp, Ttp) and the lower arm-side switching elements (Trn, Tsn, Ttn) connected to the same input lines in a conductive state and places the remaining two pairs in a non-conductive state.
  • This mode is suitable in a power converter circuit that is a so-called current-type converter or an indirect matrix converter which is capable of suppressing power supply harmonics.
  • the upper arm-side switching elements are elements which are provided on all of the upper arms of the three phases and which are respectively capable of making a current pathway conductive in only one direction from the first to third input lines (Lr, Ls, Lt) to the positive-side DC power line (L1) when in a closed state.
  • the lower arm-side switching elements are elements which are provided on all of the lower arms of the three phases and which are respectively capable of making a current pathway conductive in only one direction from the negative-side DC power line (L2) to the first to third input lines (Lr, Ls, Lt) when in a closed state.
  • control unit (300E) closes the opening/closing switch (84C) until an inrush current becomes suppressible after start of energization of the power converter circuit, and places at least switching elements (Tsn, Ttn) of an arm on a side to which the current-limiting circuit (50) is not connected among a pair of switching elements provided on upper and lower arms of one phase among phases to which the current-limiting circuit (50) is not connected in a conductive state and places the remaining switching elements in a non-conductive state.
  • This mode is suitable in a power converter circuit that is a so-called current-type converter or an indirect matrix converter which is capable of suppressing power supply harmonics.
  • the switching elements (Tlp, Tln, Tnp, Tnn) are provided on all of the upper and lower arms.
  • the control unit (300C') closes the opening/closing switch (84C) until an inrush current becomes suppressible after start of energization of the power converter circuit, and places the switching element (Tnn) on a side to which the current-limiting circuit (50) is not connected of a phase to which the current-limiting circuit (50) is not connected in a conductive state and places the remaining switching elements (Tlp, Tin, Tnp) in a non-conductive state.
  • This mode is suitable in a power converter circuit that is a so-called current-type converter or an indirect matrix converter which is capable of suppressing power supply harmonics.
  • control units when stopping charging of the capacitor (C), the control units (300A, 300C, 300D, 300E) control switching of each of the switching elements (Trp, Trn, Tsp, Tsn, Ttp, Ttn) so that the upper and lower arms of at least two phases enter a non-conductive state.
  • the switching elements function as power switches and stop supply of power from a commercial power supply, charging of the capacitor (C) can be stopped without having to use a large electromagnetic relay as a power switch.
  • control units when stopping charging of the capacitor (C), the control units (300A', 300B', 300C') control switching of each of the switching elements (Tlp, Tln, Tnp, Tnn) so that the upper and lower arms of at least one phase enter a non-conductive state.
  • the switching elements function as power switches and stop supply of power from a commercial power supply, charging of the capacitor (C) can be stopped without having to use a large electromagnetic relay as a power switch.
  • control units when stopping charging of the capacitor (C), the control units (300C, 300E) control switching of each of the switching elements (Trp, Tsp, Ttp, Trn, Tsn, Ttn) so that at least either all of the upper arms or all of the lower arms enter a non-conductive state.
  • the switching elements can be made to function as power switches and charging of the capacitor (C) can be stopped without having to use a large electromagnetic relay as a power switch.
  • control unit (300C') controls switching of each of the switching elements (Tip, Tnp, Tln, Tnn) so that at least either all of the upper arms or all of the lower arms enter a non-conductive state.
  • the switching elements can be made to function as power switches and charging of the capacitor (C) can be stopped without having to use a large electromagnetic relay as a power switch.
  • control units (300A, 300C) set a timing at which the opening/closing switch (84C) is closed until an inrush current becomes suppressible after start of energization as a timing at which a predetermined period of time in which an inrush current becomes suppressible has lapsed after the start of energization.
  • the control unit controls a period of time during which the opening/closing switch is closed by time measurement as a period of time in which a predetermined amount of time lapses. Therefore, the opening/closing switch can be kept closed in a reliable manner until a timing arrives which is determined in advance as a timing at which an inrush current becomes suppressible after the start of energization. Accordingly, an inrush current can be reliably suppressed.
  • the opening/closing switch (84C) is any of a switching element capable of unidirectional energization or a circuit that combines an electromagnetic relay and a unidirectional energizing element.
  • a current can be sent unidirectionally from a power line to which the current-limiting circuit is connected to a DC power line.
  • a stable current-limiting operation can be performed regardless of a phase relationship or a positive/negative relationship among respective phases of the power line and without allowing a current to flow in reverse from the power line side to the current-limiting circuit.
  • an interposition of the unidirectional energizing element reduces an electrical burden that acts on the moving contact of the electromagnetic relay. Accordingly, a decline in reliability of the power converter circuit due to welding-induced stiction or degradation of a moving contact can be reduced and adverse effects of the electromagnetic noise during opening and closing of the moving contact can also be reduced.
  • the power converter circuit is a power converter circuit of a power supply circuit included in an air conditioner which executes a refrigeration cycle by circulating a refrigerant in a refrigerant circuit to which a compressor, a heat source-side heat exchanger, an expansion valve, and a utilization-side heat exchanger are connected through piping.
  • control units (300A, 300C, 300D, 300E) when the control units (300A, 300C, 300D, 300E) receive a high pressure abnormality signal that is outputted when a high pressure sensor (400) which detects an abnormal rise of high pressure of the refrigeration cycle detects the abnormal rise, the control units (300A, 300C, 300D, 300E) control switching of each of the switching elements (Trp, Trn, Tsp, Tsn, Ttp, Ttn) so that the upper and lower arms of at least two phases enter a non-conductive state.
  • the power converter circuit is a power converter circuit of a power supply circuit included in an air conditioner which executes a refrigeration cycle by circulating a refrigerant in a refrigerant circuit to which a compressor, a heat source-side heat exchanger, an expansion valve, and a utilization-side heat exchanger are connected through piping.
  • control unit (300C) when the control unit (300C) receives a high pressure abnormality signal that is outputted when a high pressure sensor (400) which detects an abnormal rise of high pressure of the refrigeration cycle detects the abnormal rise, the control unit (300C) controls switching of each of the switching elements (Trp, Tsp, Ttp, Trn, Tsn, Ttn) so that at least either all of the upper arms or all of the lower arms enter a non-conductive state.
  • the power converter circuit is a power converter circuit of a power supply circuit included in an air conditioner which executes a refrigeration cycle by circulating a refrigerant in a refrigerant circuit to which a compressor, a heat source-side heat exchanger, an expansion valve, and a utilization-side heat exchanger are connected through piping.
  • control units (300A', 300B', 300C') when the control units (300A', 300B', 300C') receive a high pressure abnormality signal that is outputted when a high pressure sensor (400) which detects an abnormal rise of high pressure of the refrigeration cycle detects the abnormal rise, the control units (300A', 300B', 300C') control switching of each of the switching elements (Tlp, Tln, Tnp, Tnn) so that the upper and lower arms of at least one phase enter a non-conductive state.
  • This mode is suitable for a converter circuit of a single-phase power supply circuit that is included in an air conditioner which comprises a high pressure switch and which stops the refrigeration cycle when an abnormal rise of high pressure of the refrigeration cycle occurs.
  • the power converter circuit is a power converter circuit of a power supply circuit included in an air conditioner which executes a refrigeration cycle by circulating a refrigerant in a refrigerant circuit to which a compressor, a heat source-side heat exchanger, an expansion valve, and a utilization-side heat exchanger are connected through piping.
  • control unit (300C') when the control unit (300C') receives a high pressure abnormality signal that is outputted when a high pressure sensor (400) which detects an abnormal rise of high pressure of the refrigeration cycle detects the abnormal rise, the control unit (300C') controls switching of each of the switching elements (Tlp, Tnp, Tln, Tnn) so that at least either all of the upper arms or all of the lower arms enter a non-conductive state.
  • This mode is suitable for a converter circuit of a single-phase power supply circuit that is included in an air conditioner which comprises a high pressure switch and which stops the refrigeration cycle when an abnormal rise of high pressure of the refrigeration cycle occurs.
  • the air conditioner according to the present invention is an air conditioner comprising: a motor (M); and the power converter circuit (2A, 2A', 2B', 2C, 2C', 2D, 2E, 20A, 20A') with any one of the configurations above, wherein the power converter circuit (2A, 2A', 2B', 2C, 2C', 2D, 2E, 20A, 20A') includes a capacitor (C) connected to a converter circuit (10A, 10A', 10B', 10C, 10C', 10D, 10E, 100A, 100A') and an inverter circuit (20) connected between the capacitor (C) and the motor (M).
  • an air conditioner comprising a motor and the power converter circuit that includes a capacitor connected to a converter circuit and an inverter circuit connected between the capacitor and the motor.

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  • Air Conditioning Control Device (AREA)

Description

    Technical Field
  • The present invention relates to a power converter circuit and an air conditioner having the power converter circuit.
  • Background Art
  • A large electromagnetic relay is conventionally used in a power converter circuit comprising a converter circuit and the like. The electromagnetic relay is used as a power switch for ensuring safety when the circuit is not in use or as a power switch for cutting off and protecting a power supply when an abnormality occurs. For example, in a direct AC-AC power converter disclosed in Patent Document 1, a power switch is provided on each of three input lines from a three-phase AC power supply to a current-type converter (refer to paragraph 0037, Fig. 1, and the like).
  • Patent Document 1: Japanese Patent Application Laid-open No. 2009-95149
  • With an electromagnetic relay, a moving contact mechanically opens or closes. Therefore, welding-induced stiction or degradation of the moving contact may potentially cause reliability of the power converter circuit to decline (problem 1). In addition, electromagnetic noise occurs due to contact bounce when the moving contact opens or closes. Propagation of the electromagnetic noise to a low current circuit such as a control circuit of the power converter circuit may potentially cause the circuit to malfunction. In particular, when a connection wire to a commercial power supply is shared by a converter circuit and a low current circuit is connected to a power supply branching from the connection wire, the low curcurrent circuit is significantly affected (problem 2). Furthermore, when an electromagnetic relay is used in a power switch, the electromagnetic relay must be large. Therefore, substrate size of the power supply circuit increases (problem 3).
  • EP 2 249 471 A1 relates to a direct AC power converter. A control section controls a current-source converter while a switch is conducting, to render conducting a pair of a high-arm side transistor and a low-arm side transistor which are connected to any one of input lines, performs voltage doubler rectification on a voltage between an neutral phase input line on which a resistor is provided and any one of the input lines to serve for charging of clamp capacitors. After start of energization of the motor driving device, the switch connected to the neutral point of the three-phase-system and the middle point between the capacitors via the resistor is switched on, and in order to cause the upper and lower arms to enter a conductive state only in the R phase, the transistors Srp and Srn to enter a conductive state and the transistors Ssp, Ssn, Stp and Stn to enter a non-conductive state.
  • An object of the present invention is to provide a power converter circuit and an air conditioner which are capable of solving the problems described above.
  • Summary of the Invention
  • The present invention provides a power converter circuit according to claim 1.
  • According to the present invention, the switching elements function as power switches. Therefore, a large electromagnetic relay as a power switch can be eliminated from an input unit of a converter circuit. As a result, the following effects (1) to (3) can be obtained. (1) Since there is no longer a risk of welding-induced stiction or degrading of the moving contact of the electromagnetic relay previously used as the power switch, reliability of the converter circuit can be improved. (2) Electromagnetic noise generated when the moving contact opens and closes can be prevented from propagating to a low current circuit such as a control circuit of the power converter circuit and, in particular, to a low current circuit which shares a connection wire to a commercial power supply with the converter circuit and which is connected to a power supply branching from the connection wire. (3) A circuit board can be downsized.
  • According to the present invention, a large electromagnetic relay as a power switch can be eliminated from the power converter circuit. Therefore, according to the present invention, the reliability of the converter circuit can be improved, electromagnetic noise generated by the opening and closing of the electromagnetic relay can be prevented from propagating to a low current circuit such as a control circuit of the power converter circuit and, in particular, to a low current circuit which shares a connection wire to a commercial power supply with the converter circuit and which is connected to a power supply branching from the connection wire, and the circuit board can be downsized.
  • Brief Description of the Drawings
    • Fig. 1 is a block diagram showing a schematic configuration of a power converter circuit in a power supply circuit included in an air conditioner according to a first example.
    • Fig. 2 is a time chart showing behavior of switching elements of each phase and the like during a period from start of energization of the power converter circuit to stop of charging of a capacitor in the power supply circuit shown in Fig. 1.
    • Fig. 3 is a time chart showing behavior of switching elements of each phase and the like when a high-pressure switch is activated in the power converter circuit in the power supply circuit shown in Fig. 1.
    • Fig. 4 is a block diagram showing a schematic configuration of a power converter circuit in a power supply circuit included in an air conditioner according to another example.
    • Fig. 5 is a time chart showing behavior of switching elements of each phase and the like during a period from start of energization of the power converter circuit to stop of charging of a capacitor in the power supply circuit shown in Fig. 4.
    • Fig. 6 is a time chart showing behavior of switching elements of each phase and the like when a high-pressure switch is activated in the power converter circuit in the power supply circuit shown in Fig. 4.
    • Fig. 7 is a block diagram showing a schematic configuration of a power converter circuit in a power supply circuit included in an air conditioner according to a second example.
    • Fig. 8 is a time chart showing behavior of switching elements of each phase and the like during a period from start of energization of the power converter circuit to stop of charging of a capacitor in the power supply circuit shown in Fig. 7.
    • Fig. 9 is a time chart showing behavior of switching elements of each phase and the like when a high-pressure switch is activated in the power converter circuit in the power supply circuit shown in Fig. 7.
    • Fig. 10 is a block diagram showing a schematic configuration of a power converter circuit in a power supply circuit included in an air conditioner according to a first embodiment of the present invention.
    • Fig. 11 is a time chart showing behavior of switching elements of each phase and the like during a period from start of energization of the power converter circuit to stop of charging of a capacitor in the power supply circuit shown in Fig. 10.
    • Fig. 12 is a time chart showing behavior of switching elements of each phase and the like when a high-pressure switch is activated in the power converter circuit in the power supply circuit shown in Fig. 10.
    • Fig. 13 is a block diagram showing a schematic configuration of a power converter circuit in a power supply circuit included in an air conditioner according to another example .
    • Fig. 14 is a time chart showing behavior of switching elements of each phase and the like during a period from start of energization of the power converter circuit to stop of charging of a capacitor in the power supply circuit shown in Fig. 13.
    • Fig. 15 is a time chart showing behavior of switching elements of each phase and the like when a high-pressure switch is activated in the power converter circuit in the power supply circuit shown in Fig. 13.
    • ] Fig. 16 is a block diagram showing a schematic configuration of a power converter circuit in a power supply circuit included in an air conditioner according to an example of the first example.
    • Fig. 17 is a block diagram showing a schematic configuration of a power converter circuit in a power supply circuit included in an air conditioner according to another example of the first example.
    • Fig. 18 is a time chart showing another embodiment of switching control in the power converter circuit shown in Fig. 17.
    • Fig. 19 is a time chart showing another embodiment of switching control in the power converter circuit shown in Fig. 13.
    • Fig. 20 is a block diagram showing a schematic configuration of another mode of a power converter circuit in a power supply circuit included in an air conditioner according to the first example.
    • Fig. 21 is a block diagram showing a schematic configuration of another mode of a power converter circuit in a power supply circuit included in an air conditioner according to another example.
    Detailed Description of the Preferred Embodiments of the Invention
  • Fig. 1 is a block diagram showing a schematic configuration of a power converter circuit 2A in a power supply circuit included in an air conditioner 1A according to a first example. The air conditioner 1A comprises a refrigerant circuit (not shown) to which a compressor, a heat source-side heat exchanger, an expansion valve, and a utilization-side heat exchanger (all not shown) are connected through piping. Due to driving by the compressor, the air conditioner 1A circulates a refrigerant in the refrigerant circuit to execute a refrigeration cycle. The air conditioner 1A comprises a high pressure sensor. When high pressure of the refrigeration cycle rises abnormally, the high pressure sensor detects the abnormal rise of the high pressure and outputs a high pressure abnormality signal to the power converter circuit 2A. The power converter circuit 2A stops driving of the compressor. As a result, the refrigeration cycle stops. The high pressure sensor is not limited to any system as long as the high pressure sensor has a function of outputting the fact that a high pressure state exists. As an example of the above, in the present example, the high pressure sensor will be described as a high-pressure switch 400 which outputs a presence/absence of a high pressure abnormality in states of ON (a high pressure abnormality detection signal is outputted upon detection of high pressure abnormality)/OFF (a high pressure abnormality detection signal is not outputted).
  • A motor M is connected to the power converter circuit 2A. The compressor included in the air conditioner 1A is driven by the motor M. The power converter circuit 2A comprises a converter circuit 10A, an inverter circuit 20, a smoothing circuit 30A, a current-limiting circuit 40, a control unit 300A, a coil L, and shunt resistors R2 and R3.
  • The control unit 300A comprises a CPU (Central Processing Unit), an EEPROM (Electrically Erasable Programmable Read Only Memory), and the like. The CPU executes a control program stored in the EEPROM in advance in order to control operations of the converter circuit 10A, the inverter circuit 20, and the like.
  • The converter circuit 10A is connected to a three-phase four-wire AC power supply E3 via input lines Lr, Ls, Lt (first to third input lines) corresponding to respective phases of R, S, T and a neutral line Ln. In addition, the converter circuit 10A is connected to the inverter circuit 20 and to a smoothing capacitor C that constitutes the smoothing circuit 30A via a positive-side DC power line L1 and a negative-side DC power line L2.
  • The converter circuit 10A comprises upper arm-side switching elements Trp, Ttp and lower arm-side switching elements Trn, Ttn. The upper arm-side switching elements Trp, Ttp are respectively provided between the input lines Lr, Lt and the positive-side DC power line L1. The upper arm-side switching elements Trp, Ttp are, for example, IGBTs (Insulated Gate Bipolar Transistors). The lower arm-side switching elements Trn, Ttn are respectively provided between the negative-side DC power line L2 and the input lines Lr, Lt. The lower arm-side switching elements Trn, Ttn are, for example, IGBTs.
  • Moreover, while pairs (a pair made up of Trp and Trn and a pair made up of Ttp and Ttn) of the switching elements are respectively provided on upper and lower arms of the R phase and the T phase in the present example, pairs of the switching elements need only be respectively provided on any two phases among the three phases of R, S, T. In other words, a total of two pairs of the switching elements need only be provided.
  • Anodes of diodes Drp, Dtp, Drn, Dtn are respectively connected to the emitters of the upper arm-side switching elements Trp, Ttp and the lower arm-side switching elements Trn, Ttn. Respective collectors of the upper arm-side switching elements Trp, Ttp are connected to the input lines Lr, Lt. Respective collectors of the lower arm-side switching elements Trn, Ttn are connected to the negative-side DC power line L2. Respective cathodes of the diodes Drp, Dtp are connected to the positive-side DC power line L1. Respective cathodes of the diodes Drn, Dtn are connected to the input lines Lr, Lt. In addition, a diode Dsp is provided on the upper arm of the S phase. A diode Dsn is provided on the lower arm of the S phase.
  • Since the upper arm-side switching elements Trp, Ttp, the lower arm-side switching elements Trn, Ttn, and the diodes Drp, Dtp, Drn, Dtn are connected as described above, the upper arm-side switching elements Trp, Ttp make a current pathway conductive in only one direction from the input lines Lr, Lt to the positive-side DC power line L1 in a conductive state. In addition, the lower arm-side switching elements Trn, Ttn make a current pathway conductive in only one direction from the negative-side DC power line L2 to the input lines Lr, Lt in a conductive state. However, the upper arm-side switching elements Trp, Ttp and the lower arm-side switching elements Trn, Ttn are not limited to switching elements which make current pathways conductive in only the directions described above and may instead be bidirectional energizing elements that enable energization in two directions including toward the side of the positive-side DC power line L1 and toward the side of the negative-side DC power line L2.
  • The control unit 300A generates, as appropriate, a predetermined energization angle signal or PWM (Pulse Width Modulation) signal that is synchronized with a power supply phase as a drive signal. In addition, the control unit 300A outputs the drive signal to respective gates of the upper arm-side switching elements Trp, Ttp and the lower arm-side switching elements Trn, Ttn to appropriately switch the switching elements. Switching control of the upper and lower arm-side switching elements (the upper arm-side switching elements and the lower arm-side switching elements) of the converter circuit 10A will be described in detail later.
  • The smoothing capacitor C of the smoothing circuit 30A is, for example, an electrolytic capacitor. The smoothing capacitor C is connected to a load side of the converter circuit 10A and supplies power to the inverter circuit 20 as a voltage supply. In other words, the smoothing capacitor C smoothes power outputted by the converter circuit 10A by temporally storing and then releasing the power outputted by the converter circuit 10A. Moreover, since using a high breakdown voltage capacitor as the smoothing capacitor C increases cost, in the present example, two capacitors that are not high breakdown voltage capacitors are provided in series. By providing two capacitors connected in series in this manner, breakdown voltage characteristics that are comparable to using one high breakdown voltage capacitor as the smoothing capacitor can be achieved. Furthermore, by connecting the current-limiting circuit at a connection point between the two capacitors provided in series, low-voltage charging can be performed.
  • The inverter circuit 20 is a voltage-type inverter circuit. The inverter circuit 20 is connected to the motor M via output lines Lu, Lv, Lw corresponding to respective phases of U, V, W. In addition, the inverter circuit 20 is connected to the converter circuit 10A and the smoothing capacitor C via the positive-side DC power line L1 and the negative-side DC power line L2.
  • The inverter circuit 20 comprises upper arm-side switching elements Tup, Tvp, Twp, lower arm-side switching elements Tun, Tvn, Twn, and an inverter gate drive IC 200. The upper arm-side switching elements Tup, Tvp, Twp are respectively provided between the positive-side DC power line L1 and the output lines Lu, Lv, Lw. The upper arm-side switching elements Tup, Tvp, Twp are, for example, IGBTs. The lower arm-side switching elements Tun, Tvn, Twn are respectively provided between the output lines Lu, Lv, Lw and the negative-side DC power line L2. The lower arm-side switching elements Tun, Tvn, Twn are, for example, IGBTs.
  • Anodes of diodes Dup, Dvp, Dwp, Dun, Dvn, Dwn are respectively connected to emitters of the upper arm-side switching elements Tup, Tvp, Twp and the lower arm-side switching elements Tun, Tvn, Twn. Cathodes of the diodes Dup, Dvp, Dwp, Dun, Dvn, Dwn are respectively connected to collectors of the upper arm-side switching elements Tup, Tvp, Twp and the lower arm-side switching elements Tun, Tvn, Twn. In other words, diodes are connected in inverse-parallel to each of the upper and lower arm-side switching elements of the inverter circuit 20.
  • The inverter gate drive IC 200 receives a control signal from the control unit 300A and appropriately generates a PWM signal in accordance with the control signal as a drive signal. The inverter gate drive IC 200 outputs the drive signal to respective gates of the upper arm-side switching elements Tup, Tvp, Twp and the lower arm-side switching elements Tun, Tvn, Twn to appropriately open or close the switching elements. In other words, the inverter circuit 20 appropriately switches each of the upper and lower arm-side switching elements, converts DC power outputted from the smoothing capacitor C into AC power with a voltage and a frequency corresponding to a drive state of the motor, and outputs the AC power to windings of respective phases of the motor M. Accordingly, directions of winding currents of the respective phases of U, V, W of the motor M that is, for example, a three-phase brushless DC motor (directions in which currents iu, iv, iw respectively flow) are switched and the motor M rotationally drives.
  • The current-limiting circuit 40 is a circuit provided in order to prevent an inrush current from flowing to the smoothing capacitor C at the start of energization of the power converter circuit 2A. In this case, an inrush current refers to a spike-like large current which flows when charge is not stored in the smoothing capacitor C. The current-limiting circuit 40 is provided on the neutral line Ln. The current-limiting circuit 40 is constructed by connecting a current-limiting resistor R1 and a current-limiting switch 84C in series. The current-limiting switch is not limited to any system as long as the current-limiting switch has a function of reliably connecting and cutting off the current-limiting circuit. In the present example an electromagnetic relay will be described as the current-limiting switch. Hereinafter, the current-limiting switch will be described as being a current-limiting relay (84C).
  • The control unit 300A closes the current-limiting relay 84C at the start of energization of the power converter circuit 2A. Accordingly, a current that flows in the current-limiting circuit is suppressed by the current-limiting resistor R1 and flows to the smoothing capacitor C. As a result, charges gradually accumulate in the smoothing capacitor C. In the present example, the control unit 300A performs control involving opening the current-limiting relay 84C after the start of energization of the power converter circuit 2A and upon a lapse of a predetermined period of time in which an inrush current can be suppressed. However, a timing at which the control unit 300A opens the current-limiting relay 84C is not limited to a timing based on the lapse of a predetermined period of time as described above. As the timing described above, a wide variety of timings can be applied as long as an inrush current can be suppressed such as a point where voltage of the smoothing capacitor C is charged to or above a predetermined value or a point where an inrush current value during current-limiting falls to or below a predetermined value (this similarly applies to the respective embodiments below).
  • The coil L is provided between the converter circuit 10A and the smoothing circuit 30A on the positive-side DC power line L1. The coil L is a reactor provided in order to smooth current from the converter circuit 10A.
  • The shunt resistor R2 is provided between the converter circuit 10A and the smoothing capacitor C on the negative-side DC power line L2. The shunt resistor R3 is provided between the smoothing capacitor C and the inverter circuit 20 on the negative-side DC power line L2. The shunt resistor R2 and the shunt resistor R3 respectively measure a value of a current flowing in the converter circuit 10A and a value of a current flowing in the inverter circuit 20. The shunt resistor R2 and the shunt resistor R3 are used to provide control or protection of the converter and the inverter.
  • Moreover, an indoor unit (not shown) included in the air conditioner 1 that is provided inside an air-conditioned room is generally provided with an indoor remote controller (not shown) which is capable of communicating with a control unit (not shown) of the air conditioner. By operating the indoor remote controller, a user can turn the air conditioner 1 on or off, set an air conditioning temperature, and the like. The control unit (not shown) itself acts as the control unit 300A which issues commands regarding operation states of the power converter circuit. Alternatively, communication is carried out between a separately-provided control unit 300A and the control unit described above to issue commands regarding operation states of the power converter circuit.
  • Control of switching of the upper and lower arm-side switching elements of the converter circuit 10A and the like by the control unit 300A will be described with reference to Fig. 2. Fig. 2 is a time chart showing behavior of each pair of upper and lower arm-side switching elements of the R phase and the T phase and the like during a period from start of energization of the power converter circuit 2A to stop of charging of the smoothing capacitor C. (A) represents a state of the indoor remote controller,(C) represents a state of the current-limiting relay 84C, (D) represents a state of the pair of upper and lower arm-side switching elements Trp and Trn of the R phase connected to the input line Lr, (E) represents a state of the pair of upper and lower arm-side switching elements Ttp and Ttn of the T phase connected to the input line Lt, (F) represents a state of the respective upper and lower arm-side switching elements of the inverter circuit 20, and (G) represents a state of the motor M.
  • When the user turns on the indoor remote controller in order to start air conditioning (time t1), the control unit 300A closes the current-limiting relay 84C. Accordingly, energization of the power converter circuit 2A is started. At the same time, the control unit 300A fixes the respective pairs of upper and lower arm-side switching elements Trp, Trn and Ttp, Ttn of the R phase and the T phase to a non-conductive state. Accordingly, accumulation of charges in the smoothing capacitor C is started (time t2). In other words, the control unit 300A performs control in which only the S phase not provided with switching elements is placed in a conductive state. As a result, the control unit 300A prevents an inrush current from flowing to the smoothing capacitor C by ensuring that currents always flow through the current-limiting resistor R1.
  • Moreover, in this case, the configuration of the conductive state is not limited to the pair of upper and lower arm-side switching elements of the S phase. Alternatively, the pair of upper and lower arm-side switching elements of any one of the phases among the respective pairs of upper and lower arm-side switching elements of the R, S, T phases may be configured so as to enter a conductive state. For example, the pair of upper and lower arm side of any one phase of the respective pairs of upper and lower arm sides of the R, T phases may be provided with diodes in a similar manner to the S phase. In this case, switching elements are provided on the respective pairs of upper and lower arm sides of the other two phases. The switching elements are to be subjected by the control unit 300A to control similar to the conduction/non-conduction control of the respective pairs of upper and lower arm-side switching elements Trp, Trn and Ttp, Ttn of the R phase and the T phase described earlier.
  • Next, the control unit 300A opens the current-limiting relay 84C and, at the same time, fixes the respective pairs of upper and lower arm-side switching elements of the R phase and the T phase in a conductive state (time t3). In the present example, the time t3 at which the current-limiting relay 84C is opened is a time at which the control unit 300A has measured the lapse of a predetermined period of time described above (a predetermined period of time in which an inrush current can be suppressed) using a built-in timer or the like from the point at which the current-limiting relay 84C had been closed at time t2 (from the point at which energization of the power converter circuit 2A had been started) (as described earlier, the timing at which the current-limiting relay 84C is opened is not limited to this timing control).
  • Once accumulation of charges in the smoothing capacitor C prior to inverter operation is finished, the control unit 300A starts switching control of the respective upper and lower arm-side switching elements of the inverter circuit 20 (start of operation of the inverter circuit 20, time t4). Accordingly, driving of the motor M is started and normal operation of the air conditioner 1A is started.
  • When the user turns off the indoor remote controller in order to stop air conditioning (time t6), the control unit 300A places the respective upper and lower arm-side switching elements of the inverter circuit 20 in a non-conductive state. Accordingly, supply of power to the motor M is stopped (time t6). However, since reflux of energy of motor inductance and refrigerant circulation in the refrigerant circuit do not stop immediately, the motor M stops after briefly continuing inertia operation (time t7).
  • In order to ensure safety when stopping an operation in preparation for maintenance of a power converter, desirably, accumulation of charges in the smoothing capacitor C is stopped when the motor M is stopped to discharge the charge stored in the capacitor C. To this end, the control unit 300A subsequently places the respective pairs of upper and lower arm-side switching elements Trp, Trn and Ttp, Ttn of the R phase and the T phase in a non-conductive state and discharges the capacitor C using a discharge circuit (not shown) (time tg). Moreover, when stopping charging of the capacitor C in this manner (time t8), the control unit 300A need only control switching of each of the switching elements Trp, Trn, Ttp, Ttn so that the upper and lower arms of at least two phases of the three phases including the R phase, the T phase, and the S phase comprising the diodes Dsp, Dsn enter a non-conductive state.
  • Control of opening and closing of the upper and lower arm-side switching elements of the converter circuit 10A and the like by the control unit 300A when the high-pressure switch 400 is activated will be described with reference to Fig. 3. Fig. 3 is a time chart showing behavior of each pair of upper and lower arm-side switching elements of the R phase and the T phase and the like during a period from start of energization of the power converter circuit 2A to stop of the motor M when the high-pressure switch 400 is activated. (B) represents a state of a high pressure abnormality signal outputted when the high-pressure switch 400 is activated. Otherwise, the states represented by (A) to (G) correspond to Fig. 2.
  • Since control from the user turning on the indoor remote controller in order to start air conditioning (time t1) to the start of normal operation of the air conditioner 1A (time t4) is the same as the control described with reference to Fig. 2, a description thereof will be omitted.
  • When the high-pressure switch 400 detects an abnormal rise in high pressure of a refrigeration cycle and is activated, the high-pressure switch 400 outputs a high pressure abnormality signal to the control unit 300A. At the same time, the control unit 300A places the respective upper and lower arm-side switching elements of the inverter circuit 20 in a non-conductive state and stops the supply of power to the motor M (time t6'). Subsequently, in order to stop accumulation of charges in the smoothing capacitor C, the control unit 300A places the respective pairs of upper and lower arm-side switching elements Trp, Trn and Ttp, Ttn of the R phase and the T phase in a non-conductive state (time t7').
  • When stopping charging of the capacitor C in this manner (time t7'), the control unit 300A may control switching of each of the switching elements Trp, Trn, Ttp, Ttn so that either the upper arm-side switching elements Trp, Ttp of both the R phase and the T phase or the lower arm-side switching elements Trn, Ttn of both the R phase and the T phase enter a non-conductive state.
  • While the switching elements are placed in a non-conductive state at time t7', a similar effect can be produced by placing the switching elements in a non-conductive state at time t6' that is a timing at which the supply of power to the motor M is stopped.
  • The fact that air conditioning had stopped due to a high pressure abnormality is displayed on a display unit or the like included in the indoor remote controller so as to be visible to the user. The user having confirmed the display turns off the indoor remote controller and stops the operation of the air conditioner 1A (time t8').
  • The above description concerns an example of the power converter circuit 2A connected to the three-phase four-wire AC power E3. However, operations according to the first example (Fig. 2 and Fig. 3) can also be applied to a power converter circuit 2A' connected to a single-phase AC power supply E1. A schematic configuration of the power converter circuit 2A' in the power supply circuit included in an air conditioner 1A' is shown in Fig. 4. The power converter circuit 2A' shares the same configuration as the power converter circuit 2A with the exception of a configuration of a converter circuit 10A' that is connected to the single-phase AC power supply E1, a configuration of a smoothing circuit 30A', and the fact that a current-limiting circuit 50 is connected between an input line L1 and the positive-side DC power line L1 instead of on the neutral line. Alternatively, the current-limiting circuit 50 may be connected to the negative-side DC power line L2. In addition, two current-limiting circuits may be provided, namely, a current-limiting circuit connected to the positive-side DC power line L1 and a current-limiting circuit connected to the negative-side DC power line L2.
  • The converter circuit 10A' is connected to the single-phase AC power supply E1 via the input line L1 corresponding to an L phase and an input line Ln corresponding to an N phase. In addition, the converter circuit 10A' is connected to the inverter circuit 20 and to a smoothing capacitor C that constitutes the smoothing circuit 30A' via the positive-side DC power line L1 and the negative-side DC power line L2.
  • The converter circuit 10A' comprises an upper arm-side switching element Tip and a lower arm-side switching element Tln. The upper arm-side switching element Tlp is provided between the input line L1 and the positive-side DC power line L1. The upper arm-side switching element Tip is, for example, an IGBT. The lower arm-side switching element Tln is provided between the negative-side DC power line L2 and the input line L1. The lower arm-side switching element Tln is, for example, an IGBT. In addition, a diode Dnp is provided on an upper arm of the N phase and a diode Dnn is provided on a lower arm of the N phase.
  • Anodes of diodes Dlp, Dln are respectively connected to the emitters of the upper arm-side switching element Tlp and the lower arm-side switching element Tln. A collector of the upper arm-side switching element Tlp is connected to the input line L1. A collector of the lower arm-side switching element Tln is connected to the negative-side DC power line L2. A cathode of the diode Dlp is connected to the positive-side DC power line L1 and a cathode of the diode Dln is connected to the input line L1.
  • According to this configuration, in a similar manner to the converter circuit 10A connected to the three-phase AC power supply E3, the upper arm-side switching element Tlp switches between conduction and non-conduction of a current pathway that flows from the input line L1 to the positive-side DC power line L1 in a conductive state, and the lower arm-side switching element Tln switches between conduction and non-conduction of a current pathway that flows from the negative-side DC power line L2 to the input line Ln in a conductive state.
  • The smoothing circuit 30A' comprises a smoothing capacitor C. The smoothing capacitor C is, for example, an electrolytic capacitor. The smoothing capacitor C is connected to a load side of the converter circuit 10A' and supplies power to the inverter circuit 20 as a voltage supply. In other words, the smoothing capacitor C smoothes power outputted by the converter circuit 10A by temporally storing and then releasing the power outputted by the converter circuit 10A.
  • Control of switching of switching elements in the converter circuit 10A' and the like which is performed by the control unit 300A' included in the power converter circuit 2A' is shown in Fig. 5 and Fig. 6.
  • Fig. 5 is a time chart showing behavior of the pair of upper and lower arm-side switching elements of the L phase and the like during a period from start of energization of the power converter circuit 2A' to stop of charging of the smoothing capacitor C. (A) represents a state of the indoor remote controller, (C) represents a state of the current-limiting relay 84C, (D) represents a state of the pair of upper and lower arm-side switching elements Tlp and Tln of the L phase connected to the input line L1, (E) represents a state of the respective upper and lower arm-side switching elements of the inverter circuit 20, and (F) represents a state of the motor M. Moreover, times t1 to tg respectively correspond to times t1 to t8 in Fig. 2.
  • Fig. 6 is a time chart showing behavior of a pair of upper and lower arm-side switching elements of the N phase and the like during a period from start of energization of the power converter circuit 2A' to stop of the motor M when the high-pressure switch 400 is activated. (B) represents a state of a high pressure abnormality signal outputted when the high-pressure switch 400 is activated. Otherwise, the states represented by (A) to (F) correspond to Fig. 5. Moreover, times t1 to t8' respectively correspond to times t1 to tg' in Fig. 3.
  • As shown in Fig. 5 and Fig. 6, the control unit 300A' performs, on the pair of upper and lower arm-side switching elements Tlp and Tln of the L phase, control similar to the control performed by the control unit 300A on the respective pairs of upper and lower arm-side switching elements Trp, Trn and Ttp, Ttn of the R phase and the T phase in the converter circuit 10A connected to the three-phase AC power supply E3.
  • However, when an arm to which only a diode is connected exists on the side of a current-limiting circuit as in the case of the present example, a current may potentially flow from the power line side to the current-limiting circuit depending on a phase relationship or a positive/negative relationship among the respective phases of the power line. Therefore, the current-limiting relay 84C must be turned off at a timing at which the arm to which only a diode is connected becomes conductive. Alternatively, unwilling conduction must be prevented by using a unidirectional energizing element in the current-limiting circuit.
  • In reality, a high-accuracy detecting circuit is required to accurately detect a power supply phase or a positive/negative relationship. For this reason, an example connected to a single-phase AC power supply as is the case of the present example or an example connected to a three-phase three-wire AC power supply to be described later adopts a configuration where the current-limiting relay 84C is constituted by a switching element capable of unidirectional energization or a configuration where the current-limiting relay 84C is constituted by a circuit that combines an electromagnetic relay and a unidirectional energizing element. Adopting such a configuration enables a current to be sent unidirectionally from a power line to which the current-limiting circuit is connected to a DC power line and prevents a current from flowing in reverse from the power line side to the current-limiting circuit regardless of the phase relationship or a positive/negative relationship among the respective phases of the power line. As a result, a stable current-limiting operation can be performed with a simple circuit configuration.
  • In addition, when stopping accumulation of charges in the smoothing capacitor C upon stop of the motor M (time t8) in the switching control shown in Fig. 5 and Fig. 6, the control unit 300A' need only control the current-limiting relay (84C) and control switching of the respective elements so that the upper and lower arm-side switching elements of the L phase enter a non-conductive state. Moreover, a control unit 300B' of a power converter circuit 2B' shown in Fig. 7 and a control unit 300C' of a power converter circuit 2C' shown in Fig. 13 (to be described later) also need only perform switching control in a similar manner when stopping charging of the smoothing capacitor C (time t8).
  • According to the first example, a large electromagnetic relay as a power switch can be eliminated from the power converter circuits 2 and 2'. As a result, the following effects (1) to (3) can be obtained. (1) Since there is no longer a risk of welding-induced stiction or degrading of the moving contact of the electromagnetic relay previously used as the power switch, the reliability of the converter circuits 10A and 10A' can be improved. (2) Noise generated when the moving contact opens and closes can be prevented from propagating to a low current circuit such as a control circuit of the power converter circuit and, in particular, to a low current circuit which shares the input lines Lr, Ls, Lt, Ll, Ln that act as connection wires to the commercial power supply E1 or E3 with the converter circuit 10A or 10A' and which is connected to a power supply branching from the input lines Lr, Ls, Lt, Ll, Ln. (3) A circuit board of the power converter circuit 2 can be downsized.
  • In addition, according to the first example, the respective switching elements included in the converter circuits 10A and 10A' function as power switches. Therefore, charging of the smoothing capacitor C can be stopped without having to use a large electromagnetic relay as a power switch.
  • Fig. 7 is a block diagram showing a schematic configuration of a power converter circuit 2B' in a power supply circuit included in an air conditioner 1B' according to a second example. The power converter circuit 2B' that is connected to a single-phase AC power supply E1 differs from the power converter circuit 2A' in a configuration of a converter circuit 10B'. Specifically, in the converter circuit 10B', upper arm-side switching elements Tlp, Tnp which are, for example, IGBTs are respectively provided between input lines Ll, Ln and the positive-side DC power line L1. In the converter circuit 10B', switching elements are not provided between the negative-side DC power line L2 and the input lines Ll, Ln. Moreover, wire connections of the current-limiting circuit 50 are similar to those of the power converter circuit 2A' according to the first example.
  • Anodes of diodes Dlp and Dnp are respectively connected to emitters of the upper arm-side switching elements Tlp and Tnp. Respective collectors of the upper arm-side switching elements Tlp and Tnp are connected to the input lines Ll and Ln.
  • Diodes Dln and Dnn are respectively provided on lower arms of the L phase and the N phase. Cathodes of the diodes Dln, Dnn are respectively connected to the input lines Ll, Ln, and anodes of the diodes Dln, Dnn are respectively connected to the negative-side DC power line L2.
  • According to this configuration, the upper arm-side switching elements Tlp and Tnp make a current pathway conductive in only one direction from the input lines Ll and Ln to the positive-side DC power line L1 in a conductive state. This is similar to the power converter circuit 2A' according to the first example. Since the configuration other than the converter circuit 10B' is similar to that of the power converter circuit 2A', a description thereof will be omitted.
  • The configuration of the converter circuit 10B' in the power converter circuit 2B' differs from the configuration of the converter circuit 10A' in the power converter circuit 2A'. Therefore, switching control of the switching elements in the converter circuit 10B' which is performed by the control unit 300B' in the power converter circuit 2B' differs from the switching control of the switching elements in the converter circuit 10A' which is performed by the control unit 300A' in the power converter circuit 2A'.
  • Fig. 8 is a time chart showing behavior of upper arm-side switching elements of the L phase and the N phase and the like during a period from start of energization of the power converter circuit 2B' to stop of charging of the smoothing capacitor C. (A) represents a state of the indoor remote controller, (C) represents a state of the current-limiting relay 84C, (D) represents a state of the upper arm-side switching element Tlp of the L phase connected to the input line Ll, (E) represents a state of the upper arm-side switching element Tnp of the N phase connected to the input line Ln, (F) represents a state of the respective upper and lower arm-side switching elements of the inverter circuit 20, and (G) represents a state of the motor M. Moreover, times t1 to t8 respectively correspond to times t1 to tg in Fig. 5.
  • When the user turns on the indoor remote controller in order to start air conditioning (time t1), the control unit 300B' closes the current-limiting relay 84C and, at the same time, fixes the upper arm-side switching elements Tlp and Tnp of the L phase and the N phase to a non-conductive state to start accumulation of charges in the smoothing capacitor C (time t2).
  • Next, the control unit 300B' opens the current-limiting relay 84C and, at the same time, fixes the upper arm-side switching elements Tlp and Tnp of the L phase and the N phase in a conductive state (time t3). In the present example, the time t3 at which the current-limiting relay 84C is opened is, for example, a time at which the control unit 300B' has measured the lapse of the predetermined period of time described earlier (a predetermined period of time in which an inrush current can be suppressed) using a built-in timer or the like from the point at which the current-limiting relay 84C had been closed at time t2 (from the point at which energization of the power converter circuit 2B' had been started).
  • Once accumulation of charges in the smoothing capacitor C is finished, the control unit 300B' starts switching control of the respective upper and lower arm-side switching elements of the inverter circuit 20 (time t4). Accordingly, driving of the motor M is started and normal operation of the air conditioner 1B' is started.
  • When the user turns off the indoor remote controller in order to stop air conditioning (time t6), the control unit 300B' places the respective upper and lower arm-side switching elements of the inverter circuit 20 in a non-conductive state and stops supply of power to the motor M (time t6). The motor M stops after briefly continuing inertia operation (time t7).
    Next, the control unit 300B' places the upper arm-side switching elements Tlp and Tnp of the L phase and the N phase in a non-conductive state (time t8).
  • Fig. 9 is a time chart showing behavior of upper arm-side switching elements of the L phase and the N phase and the like during a period from start of energization of the power converter circuit 2B' to stop of the motor M when the high-pressure switch 400 is activated. (B) represents a state of a high pressure abnormality signal outputted when the high-pressure switch 400 is activated. Otherwise, the states represented by (A) to (G) correspond to Fig. 8. Moreover, times t1 to t8' respectively correspond to times t1 to t8' in Fig. 6.
  • Since control from the user turning on the indoor remote controller in order to start air conditioning (time t1) to the start of normal operation of the air conditioner 1B' (time t4) is the same as the control described with reference to Fig. 8, a description thereof will be omitted.
  • As shown in Fig. 9, when the high-pressure switch 400 is activated, the control unit 300B' places the respective upper and lower arm-side switching elements of the inverter circuit 20 in a non-conductive state and stops the supply of power to the motor M (time t6'). Next, in order to stop accumulation of charges in the smoothing capacitor C, the control unit 300B' places upper arm-side switching elements Tlp and Tnp of an L phase and the N phase in a non-conductive state (time t7').
  • The fact that air conditioning had stopped due to a high pressure abnormality is displayed on, for example, a display unit included in the indoor remote controller. In a similar manner to the air conditioner 1A' according to the first example, the user having confirmed the display turns off the indoor remote controller and stops the operation of the air conditioner 1B' (time t8').
  • A similar effect to the configuration according to the first example can also be produced by the configuration according to the second example described earlier.
  • Moreover, only the lower arm-side element of the N phase may be fixed to a conductive state in the power converter circuit 2B'. In this case, the pair of upper and lower arm-side elements of the L phase and the upper arm-side element of the N phase act as switching elements that are switchable between conduction and non-conduction. In addition, for example, a diode or the like is used as the lower arm-side element of the N phase.
  • In other words, when stopping accumulation of charges in the smoothing capacitor C upon stop of the motor M (time t8) in the switching control shown in Fig. 8 and Fig. 9, the control unit 300B' need only control switching of the respective elements so that the pair of upper and lower arm-side switching elements of the L phase and the upper arm-side element of the N phase remain in a non-conductive state and the current-limiting relay (84C) enters a non-conductive state.
  • <First embodiment>
  • Fig. 10 is a block diagram showing a schematic configuration of a power converter circuit 2C in a power supply circuit included in an air conditioner 1C according to a first embodiment of the present invention. The power converter circuit 2C differs from the power converter circuit 2A in a configuration of a converter circuit 10C. The converter circuit 10C is a so-called current-type converter circuit which comprises an IGBT connected in series to a diode on all upper and lower arms of three phases. In the power converter circuit 2C, the converter circuit 10C is capable of suppressing generation of power supply harmonics through, for example, PWM control.
  • In addition, the power converter circuit 2C comprises a smoothing circuit 30C similar to that of the power converter circuit 2A. The smoothing capacitor C is, for example, an electrolytic capacitor. The power converter circuit 2C has a similar configuration to the power converter circuit 2A in that the smoothing capacitor C is connected to a load side of the converter circuit 10C, the smoothing capacitor C supplies power to the inverter circuit 20 as a voltage supply, two capacitors that are not high breakdown voltage capacitors are provided in series to constitute the smoothing capacitor C, and the like.
  • The converter circuit 10C will be described in detail below. The converter circuit 10C comprises upper arm-side switching elements Trp, Tsp, Ttp, lower arm-side switching elements Trn, Tsn, Ttn, and a converter gate drive IC 100. The upper arm-side switching elements Trp, Tsp, Ttp are respectively provided between input lines Lr, Ls, Lt and the positive-side DC power line L1. The upper arm-side switching elements Trp, Tsp, Ttp are, for example, IGBTs. The lower arm-side switching elements Trn, Tsn, Ttn are respectively provided between the negative-side DC power line L2 and the input lines Lr, Ls, Lt. The lower arm-side switching elements Trn, Tsn, Ttn are, for example, IGBTs.
  • Anodes of diodes Drp, Dsp, Dtp, Drn, Dsn, Dtn are respectively connected to emitters of the upper arm-side switching elements Trp, Tsp, Ttp and the lower arm-side switching elements Trn, Tsn, Ttn. Respective collectors of the upper arm-side switching elements Trp, Tsp, Ttp are connected to the input lines Lr, Ls, Lt. Respective collectors of the lower arm-side switching elements Trn, Tsn, Ttn are connected to the negative-side DC power line L2. Respective cathodes of the diodes Drp, Dsp, Dtp are connected to the positive-side DC power line L1, and respective cathodes of the diodes Drn, Dsn, Dtn are connected to the input lines Lr, Ls, Lt.
  • Since the upper arm-side switching elements Trp, Tsp, Ttp, the lower arm-side switching elements Trn, Tsn, Ttn, and the diodes Drp, Dsp, Dtp, Drn, Dsn, Dtn are connected as described above, the upper arm-side switching elements Trp, Tsp, Ttp make a current pathway conductive in only one direction from the input lines Lr, Ls, Lt to the positive-side DC power line L1 in a conductive state. In addition, the lower arm-side switching elements Trn, Tsn, Ttn make a current pathway conductive in only one direction from the negative-side DC power line L2 to the input lines Lr, Ls, Lt in a conductive state. However, the upper arm-side switching elements Trp, Tsp, Ttp and the lower arm-side switching elements Trn, Tsn, Ttn are not limited to switching elements which make current pathways conductive in only the directions described above and may instead be bidirectional energizing elements that enable energization in two directions including toward the side of the positive-side DC power line L1 and toward the side of the negative-side DC power line L2. Alternatively, a circuit capable of bidirectional energization may be constructed by further connecting, in parallel, a circuit that performs energization only in a direction opposite to that described above. This configuration can be made comparable to a one-way energizing element by turning off a one-way energizing side.
  • The converter gate drive IC 100 receives a control signal from the control unit 300C and appropriately generates a PWM signal in accordance with the control signal as a drive signal. The converter gate drive IC 100 outputs the drive signal to respective gates of the upper arm-side switching elements Trp, Tsp, Ttp and the lower arm-side switching elements Trn, Tsn, Ttn to appropriately switch the switching elements. In other words, unlike a diode bridge-type converter circuit, the converter circuit 10C switches the upper arm-side switching elements Trp, Tsp, Ttp and the lower arm-side switching elements Trn, Tsn, Ttn and actively performs waveform control to rectify AC power. Therefore, generation of power supply harmonics due to rectification can be suppressed compared to a converter circuit that includes an arm solely constituted by a diode bridge.
  • Moreover, descriptions of the inverter circuit 20, the current-limiting circuit 40, the high-pressure switch 400, and the shunt resistor R2 and the shunt resistor R3 which share the same configurations as those in the power converter circuit 2A according to the first example will be omitted.
  • The configuration of the converter circuit 10C included in the power converter circuit 2C differs from the configuration of the converter circuit 10A included in the power converter circuit 2A. Therefore, switching control of the switching elements in the converter circuit 10C which is performed by the control unit 300C included in the power converter circuit 2C differs from the switching control of the switching elements in the converter circuit 10A which is performed by the control unit 300A included in the power converter circuit 2A.
  • Switching control of the upper and lower arm-side switching elements of the converter circuit 10C will be described with reference to Fig. 11. Fig. 11 is a time chart showing behavior of respective pairs of upper and lower arm-side switching elements of the R, S, T phases and the like during a period from start of energization of the power converter circuit 2C to stop of charging of the smoothing capacitor C. (A) represents a state of the indoor remote controller, (C) represents a state of the current-limiting relay 84C, (D) represents a state of the pair of upper and lower arm-side switching elements Trp and Trn of the R phase connected to the input line Lr, (E) represents a state of the pair of upper and lower arm-side switching elements Tsp and Tsn of the S phase connected to the input line Ls, (F) represents a state of the pair of upper and lower arm-side switching elements Ttp and Ttn of the T phase connected to the input line Lt, (G) represents a state of the respective upper and lower arm-side switching elements of the inverter circuit 20, and (H) represents a state of the motor M. Moreover, times t1 to t8respectively correspond to times t1 to t8in Fig. 2 .
  • When the user turns on the indoor remote controller in order to start air conditioning (time t1), the control unit 300C closes the current-limiting relay 84C. At the same time, among the respective pairs of upper and lower arm-side switching elements of the R, S, T phases, the control unit 300C fixes only the pair of upper and lower arm-side switching elements Tsp and Tsn of the S phase in a conductive state and fixes the pairs of upper and lower arm-side switching elements Trp, Trn and Ttp, Ttn of the remaining R and T phases in a non-conductive state. Accordingly, accumulation of charges in the smoothing capacitor C is started (time t2). In other words, the control unit 300C performs control in which only the pair of upper and lower arm-side switching elements Tsp and Tsn of the S phase is fixed in a conductive state and only the S phase is placed in a conductive state. As a result, the control unit 300C prevents an inrush current from flowing to the smoothing capacitor C by ensuring that
    currents always flow through the current-limiting resistor R1 in a similar manner to the power converter circuit 2A according to the first example. Moreover, in this case, a switching element that is fixed to a conductive state by the control unit 300C is not limited to the pair of upper and lower arm-side switching elements of the S phase. Among the respective pairs of upper and lower arm-side switching elements of the R, S, T phases, the control unit 300C may alternatively fix only the pair of upper and lower arm-side switching elements of any one of the phases in a conductive state and fix the pairs of upper and lower arm-side switching elements of the remaining two phases in a non-conductive state.
  • Next, the control unit 300C opens the current-limiting relay 84C and, at the same time, fixes the upper and lower arm-side switching elements of all three phases in a conductive state (time t3). In the present embodiment, the time t3 is, for example, a time at which the control unit 300C has measured the lapse of the predetermined period of time described earlier (a predetermined period of time in which an inrush current can be suppressed) using a built-in timer or the like from the point at which the current-limiting relay 84C had been closed at time t2 (from the point at which energization of the power converter circuit 2C had been started). Once accumulation of charges in the smoothing capacitor C is finished, the control unit 300C starts switching control of the respective upper and lower arm-side switching elements of the inverter circuit 20 (start of operation of the inverter circuit 20, time t4). Accordingly, driving of the motor M is started. Moreover, for example, switching according to a 120-degree energization method that is synchronized with a zero cross of the power supply may be performed as control of the respective upper and lower arm-side switching elements from time t3 to time t4.
  • Subsequently, the control unit 300C starts a synchronized operation in which the converter circuit 10C and the inverter circuit 20 are synchronized and controlled, and starts switching control of the respective upper and lower arm-side switching elements of the converter circuit 10C (start of normal operation of the air conditioner 1, time t5). The power converter circuit 2C according to the first embodiment differs from the power converter circuit 2A according to the first example in this regard.
  • When the user turns off the indoor remote controller in order to stop air conditioning (time t6), the control unit 300C places the respective upper and lower arm-side switching elements of the inverter circuit 20 in a non-conductive state and stops supply of power to the motor M (time t6). The motor M stops after briefly continuing inertia operation (time t7). Subsequently, in order to stop accumulation of charges in the smoothing capacitor C when stopping the motor M, the control unit 300C places the upper and lower arm-side switching elements of all three phases R, S, T in a non-conductive state (time t8). When stopping charging of the capacitor C in this manner (time t8), the control unit 300C may control switching of each of the switching elements Trp, Trn, Tsp, Tsn, Ttp, Ttn so that the upper and lower arms of at least two phases among the three phases R, S, T enter a non-conductive state. Moreover, a control unit 300D of a power converter circuit 2D shown in Fig. 16 and a control unit 300E of a power converter circuit 2E shown in Fig. 17 (to be described later) may also perform switching control in a similar manner when stopping charging of the smoothing capacitor C (time t8).
  • In addition, when stopping charging of the capacitor C in this manner (time t8), the control unit 300C may control switching of each of the switching elements Trp, Trn, Tsp, Tsn, Ttp, Ttn so that either the upper arm-side switching elements Trp, Tsp, Ttp of all three phases R, S, T or the lower arm-side switching elements Trn, Tsn, Ttn of all three phases R, S, T enter a non-conductive state. This also applies to the control performed by the control unit 300E of the power converter circuit 2E shown in Fig. 14 to be described below.
  • Opening/closing control of the upper and lower arm-side switching elements of the converter circuit 10C when the high-pressure switch 400 is activated will be described with reference to Fig. 12. Fig. 12 is a time chart showing behavior of each pair of upper and lower arm-side switching elements of the R, S, T phases and the like during a period from start of energization of the power converter circuit 2C to stop of the motor M when the high-pressure switch 400 is activated. (B) represents a state of a high pressure abnormality signal outputted when the high-pressure switch 400 is activated. Otherwise, the states represented by (A) to (H) correspond to Fig. 11. Moreover, times t1 to t8' respectively correspond to times t1 to t8' in Fig. 3.
  • Since control from the user turning on the indoor remote controller in order to start air conditioning (time t1) to the start of normal operation of the air conditioner 1C (time t5) is the same as the control described with reference to Fig. 11, a description thereof will be omitted.
  • When the high-pressure switch 400 detects an abnormal rise in high pressure of a refrigeration cycle and is activated, the high-pressure switch 400 outputs a high pressure abnormality signal to the control unit 300C. At the same time, the control unit 300C places the respective upper and lower arm-side switching elements of the inverter circuit 20 in a non-conductive state and stops the supply of power to the motor M (time t6'). Subsequently, in order to stop accumulation of charges in the smoothing capacitor C, the control unit 300C places the upper and lower arm-side switching elements of all three phases R, S, T in a non-conductive state (time t7').
  • When stopping charging of the capacitor C in this manner (time t7'), the control unit 300C may control switching of each of the switching elements Trp, Trn, Tsp, Tsn, Ttp, Ttn so that the upper and lower arms of at least two phases among the three phases R, S, T enter a non-conductive state. Moreover, a control unit 300D of a power converter circuit 2D shown in Fig. 16 and a control unit 300E of a power converter circuit 2E shown in Fig. 17 (to be described later) may also perform switching control in a similar manner when stopping charging of the smoothing capacitor C (time t8).
  • In addition, when stopping charging of the capacitor C in this manner (time t7'), the control unit 300C may control switching of each of the switching elements Trp, Trn, Tsp, Tsn, Ttp, Ttn so that either the upper arm-side switching elements Trp, Tsp, Ttp of all three phases R, S, T or the lower arm-side switching elements Trn, Tsn, Ttn of all three phases R, S, T enter a non-conductive state. This also applies to the control performed by the control unit 300E of the power converter circuit 2E shown in Fig. 14 to be described below.
  • The fact that air conditioning had stopped due to a high pressure abnormality is displayed on, for example, a display unit included in the indoor remote controller. In a similar manner to the air conditioner 1A according to the first example, the user having confirmed the display turns off the indoor remote controller and stops the operation of the air conditioner 1C (time t8').
  • Moreover, in a similar manner to the first example, the configuration of the first embodiment can also be applied to a power converter circuit 2C' that is connected to the single-phase AC power supply E1. A schematic configuration of the power converter circuit 2C' in the power supply circuit included in an air conditioner 1C' is shown in Fig. 13. The power converter circuit 2C' differs from the power converter circuit 2C in a configuration of a converter circuit 10C' connected to the single-phase AC power supply E1, in a configuration of a smoothing circuit 30C', and in wire connections of a current-limiting circuit 50. The smoothing circuit 30C' shares the same configuration as the smoothing circuit 30A' shown in Fig. 4. Otherwise, the configuration of the power converter circuit 2C' is similar to that of the power converter circuit 2C. Moreover, wire connections of the current-limiting circuit 50 are similar to those of the power converter circuits 2A' and 2B' according to the first and second examples.
  • The converter circuit 10C' comprises upper arm-side switching elements Tlp, Tnp, lower arm-side switching elements Tln, Tnn, and a converter gate drive IC 100'. The upper arm-side switching elements Tlp, Tnp are respectively provided between the input lines L1, Ln and the positive-side DC power line L1. The upper arm-side switching elements Tlp, Tnp are, for example, IGBTs. The lower arm-side switching elements Tln, Tnn are respectively provided between the negative-side DC power line L2 and the input lines L1, Ln. The lower arm-side switching elements Tln, Tnn are, for example, IGBTs.
  • Anodes of diodes Dlp, Dnp, Dln, Dnn are respectively connected to emitters of the upper arm-side switching elements Tlp, Tnp and the lower arm-side switching elements Tln, Tnn. Respective collectors of the upper arm-side switching elements Tlp and Tnp are connected to the input lines L1 and Ln. Respective collectors of the lower arm-side switching elements Tln and Tnn are connected to the negative-side DC power line L2. Respective cathodes of the diodes Dlp and Dnp are connected to the positive-side DC power line L1, and respective cathodes of the diodes Dln and Dnn are connected to the input lines L1 and Ln.
  • According to this configuration, in a similar manner to the converter circuit 10C connected to the three-phase AC power supply E3, the upper arm-side switching elements Tlp and Tnp make a current pathway conductive in only one direction from the input lines L1 and Ln to the positive-side DC power line L 1 in a conductive state, and the lower arm-side switching elements Tln and Tnn make a current pathway conductive in only one direction from the negative-side DC power line L2 to the input lines L1 and Ln in a conductive state.
  • Control of opening and closing of switching elements in the converter circuit 10C' and the like which is performed by the control unit 300C' included in the power converter circuit 2C' is shown in Fig. 14 and Fig. 15 .
  • Fig. 14 is a time chart showing behavior of respective upper and lower arm-side switching elements and the like during a period from start of energization of the power converter circuit 2C' to stop of charging of the smoothing capacitor C. (A) represents a state of the indoor remote controller, (C) represents a state of the current-limiting relay 84C, (D) represents a state of the upper and lower arm-side switching elements Tlp and Tln of the L phase connected to the input line L1, (E) represents a state of the upper and lower arm-side switching elements Tnp and Tnn of the N phase connected to the input line Ln, (F) represents a state of the respective upper and lower arm-side switching elements of the inverter circuit 20, and
    (G) represents a state of the motor M. Moreover, times t1 to t8 respectively correspond to times t1 to t8 in Fig. 11.
  • Moreover, when stopping charging of the capacitor C in this manner (time t8), the control unit 300C' may control switching of each of the switching elements Tlp, Tnp, Tln, Tnn so that either the upper arm-side switching elements Tlp, Tnp of both the L phase and the N phase or the lower arm-side switching elements Tin, Tnn of both the L phase and the N phase enter a non-conductive state.
  • Fig. 15 is a time chart showing behavior of respective upper and lower arm-side switching elements and the like during a period from start of energization of the power converter circuit 2C' to stop of the motor M when the high-pressure switch 400 is activated. (B) represents a state of a high pressure abnormality signal outputted when the high-pressure switch 400 is activated. Otherwise, the states represented by (A) to (G) correspond to Fig. 14. Moreover, times t1 to t8' respectively correspond to times t1 to t8' in Fig. 12.
  • As shown in Fig. 14 and Fig. 15, the control unit 300C' performs, on the upper and lower arm-side switching elements Tnp and Tnn of the N phase, control similar to that performed by the control unit 300C on the upper and lower arm-side switching elements of the S phase in the converter circuit 10C connected to the AC power supply E3. In addition, the control unit 300C' performs, on the upper and lower arm-side switching elements Tlp and Tin of the L phase, control similar to that performed by the control unit 300C on the upper and lower arm-side switching elements of the R phase and the T phase in the converter circuit 10C.
  • Moreover, the power converter circuit 2C' may control the respective upper and lower arm-side switching elements and the like during a period from start of energization of the power converter circuit 2C' to stop of charging of the smoothing capacitor C as depicted in the time chart shown in Fig. 19.
  • Specifically, when the user turns on the indoor remote controller in order to start air conditioning (time t1), the control unit 300C' closes the current-limiting relay 84C. Accordingly, energization of the power converter circuit 2C' is started. At the same time, the control unit 300C' fixes, to a conductive state, the lower arm-side switching element Tnn of the N phase which is a switching element of an arm on a side to which the current-limiting circuit 50 is not connected in a phase to which the current-limiting circuit 50 is not connected. In addition, the control unit 300C' places the remaining switching elements or, in other words, the pair of upper and lower arm-side switching elements Tlp, Tln of the L phase and the upper arm-side switching element Tnp of the N phase in a non-conductive state and starts accumulation of charges in the smoothing capacitor C (time t2). As a result, the control unit 300C' prevents an inrush current from flowing to the smoothing capacitor C by ensuring that currents always flow through the current-limiting resistor R1.
  • Next, the control unit 300C' opens the current-limiting relay 84C and, at the same time, fixes all of the switching elements of the L phase and the N phase in a conductive state (time t3). Similarly, in the present example, the time t3is, for example, a time at which the control unit 300C' has measured the lapse of the predetermined period of time described earlier (a predetermined period of time in which an inrush current can be suppressed) using a built-in timer or the like from the point at which the current-limiting relay 84C had been closed at time t2(from the point at which energization of the power converter circuit 2C' had been started).
  • Once accumulation of charges in the smoothing capacitor C is finished, the control unit 300C' starts switching control of the respective upper and lower arm-side switching elements of the inverter circuit 20 (start of operation of the inverter circuit 20, time t4). Accordingly, driving of the motor M is started. Since subsequent control is similar to the control shown in Fig. 14 , a description thereof will be omitted.
  • Moreover, when stopping charging of the capacitor C in this manner (time t8 in Fig. 14, time t7' in Fig. 15, time t8' in Fig. 19), the control unit 300C' may control switching of each of the switching elements Tlp, Tnp, Tln, Tnn so that the current-limiting relay (84C) and either all of the upper arm-side switching elements Tlp, Tnp of the L phase and the N phase or all of the lower arm-side switching elements Tln, Tnn of the L phase and the N phase enter a non-conductive state.
  • According to the first embodiment, since the control unit 300C or 300C' switches the respective upper and lower arm-side switching elements and actively performs waveform control to rectify AC power, generation of power supply harmonics due to rectification can be suppressed. Other effects are similar to those produced by the first and second examples.
  • While air conditioners and power converter circuits have been described above, the present invention is not limited to the above examples and the embodiment.
    1. (1) While a wire connection of the three-phase AC power supply E3 according to the first example and the first embodiment adopts a three-phase four-wire system it can also be applied to a case where the wire connection of the three-phase AC power supply E3 adopts a three-phase three-wire system. Fig. 16 shows a configuration of a power converter circuit 2D resulting from applying a wire connection of a three-phase three-wire system to the configuration of the power converter circuit 2A according to the first example. Fig. 17 shows a configuration of a power converter circuit 2E resulting from applying a wire connection of a three-phase three-wire system to the configuration of the power converter circuit 2C according to the first embodiment.
  • In this configuration in which the wire connection of the three-phase AC power supply E3 adopts a three-phase three-wire system, in a similar manner to the case of a single phase, the current-limiting circuit 50 is provided between
    any one of input lines Lr, Ls, Lt and any one of the positive-side DC power line L1 and the negative-side DC power line L2 (in the examples shown in Fig. 16 and Fig. 17, between the input line Lr and the positive-side DC power line L1) instead of on the neutral line Ln.
  • When wire connection of a three-phase three-wire system is applied to the power converter circuit 2A according to the first example, in order to ensure that currents flow through a current-limiting resistor during a current-limiting operation, switching elements must be provided on upper and lower arms of a phase to which the current-limiting circuit 50 is connected.
  • Even in these cases, in a similar manner to the power converter circuit 2C shown in Fig. 10, the upper arm-side switching elements Trp, Ttp and the lower arm-side switching elements Trn, Ttn in the power converter circuit 2D are not limited to switching elements which make current pathways conductive in only the directions described above and may instead be bidirectional energizing elements that enable energization in two directions including toward the side of the positive-side DC power line L1 and toward the side of the negative-side DC power line L2. In addition, the upper arm-side switching elements Trp, Tsp, Ttp and the lower arm-side switching elements Trn, Tsn, Ttn in the power converter circuit 2E are not limited to switching elements which make current pathways conductive in only the directions described above and may instead be bidirectional energizing elements that enable energization in two directions including toward the side of the positive-side DC power line L1 and toward the side of the negative-side DC power line L2. Alternatively, a circuit capable of bidirectional energization may be constructed by further connecting, in parallel, a circuit that performs energization only in a direction opposite to that described above. This configuration can be made comparable to a one-way energizing element by turning off a one-way energizing side.
  • Another embodiment of switching control in a power converter circuit 2E shown in Fig. 17 will be described with reference to the time chart shown in Fig. 18. When the user turns on the indoor remote controller in order to start air conditioning (time t1), a control unit 300E closes the current-limiting relay 84C and causes energization of the power converter circuit 2E to start. At the same time, the control unit 300E fixes the lower arm-side switching element Tsn of the S phase (a switching element of an arm to which the current-limiting circuit 50 is not connected of at least one phase among phases to which the current-limiting circuit 50 is not connected) to a conductive state, and fixes remaining switching elements or, in other words, the upper arm-side switching element Tsp of the S phase, the pair of upper and lower arm-side switching elements Trp, Trn of the R phase, and the pair of upper and lower arm-side switching elements Ttp, Ttn of the T phase in a non-conductive state to start accumulation of charges in the smoothing capacitor C (time t2). As a result, the control unit 300E prevents an inrush current from flowing to the smoothing capacitor C by ensuring that currents always flow through the current-limiting resistor R1.
  • Moreover, in this case, a switching element that is placed in a conductive state by the control unit 300E is not limited to the lower arm-side switching element Tsn of the S phase and may instead be the lower arm-side switching element Ttn of the T phase or both lower arm-side switching elements of the S phase and the T phase. In this case, all of the remaining switching elements are placed in a non-conductive state.
  • Next, the control unit 300E opens the current-limiting relay 84C and, at the same time, fixes the respective pairs of upper and lower arm-side switching elements of the R phase, S phase, and the T phase in a conductive state (time t3). Similarly, in the present embodiment, the time t3is a time at which the control unit 300E has measured the lapse of the predetermined period of time described earlier (a predetermined period of time in which an inrush current can be suppressed) using a built-in timer or the like from the point at which the current-limiting relay 84C had been closed at time t2(from the point at which energization of the power converter circuit 2A had been started).
  • Once accumulation of charges in the smoothing capacitor C is finished, the control unit 300E starts switching control of the respective upper and lower arm-side switching elements of the inverter circuit 20 (start of operation of the inverter circuit 20, time t4). Accordingly, driving of the motor M is started. Since subsequent control is similar to the control by the control unit 300C shown in Fig. 11, a description thereof will be omitted.
  • Moreover, since control of switching of upper and lower arm-side switching elements of the converter circuit 10D and the like by the control unit 300D included in the power converter circuit 2D shown in Fig. 16 is similar to the control by the control unit 300A, a description thereof will be omitted.
    • (2) While IGBTs and diodes are connected in series in the converter circuits 10A to 10C' according to the first and second examples and to the first embodiment, a similar function can be provided by using reverse blocking IGBTs in the converter circuits 10A to 10C'.
    • (3) While a rectifier circuit including an arm having only a diode and a rectifier circuit having switching elements on all arms have been shown in the first and second examples and to the first embodiment, it can also be applied to an indirect matrix converter in addition to the converter circuits 10A to 10C'. Moreover, in this case, a capacitor is provided between an inverter unit and a converter unit as a clamp capacitor which constitutes a clamp circuit.
  • Fig. 20 shows an air conditioner IF comprising an indirect matrix converter 20A as a power converter circuit. The indirect matrix converter 20A comprises a current-type converter 100A, a clamp circuit 30A', and a voltage-type inverter 20.
  • The current-type converter 100A is connected to a three-phase four-wire AC power supply E3 via input lines Lr, Ls, Lt (first to third input lines) corresponding to respective phases of R, S, T and a neutral line Ln. In addition, the current-type converter 100A is connected via the positive-side DC power line L1 and the negative-side DC power line L2 to the inverter circuit 20 and the clamp circuit 30A'.
  • Switching operations of the current-type converter 100A are controlled by a control circuit 300A.
  • In the present embodiment, the current-type converter 100A comprises six sets of elements so as to correspond to upper and lower arms of the three phases, with a diode and an IGBT connected in series in each element. The respective elements are an IGBT Trp and a diode Drp, an IGBT Trn and a diode Drn, an IGBT Tsp and a diode Dsp, an IGBT Tsn and a diode Dsn, an IGBT Ttp and a diode Dtp, and an IGBT Ttn and a diode Dtn.
  • An emitter of the transistor Trp is connected to an anode of the diode Drp, and a cathode of the diode Drp is connected to the DC power line L1. An emitter of the transistor Tsp is connected to an anode of the diode Dsp, and a cathode of the diode Dsp is connected to the DC power line L1. An emitter of the transistor Ttp is connected to an anode of the diode Dtp, and a cathode of the diode Dtp is connected to the DC power line L1.
  • An anode of the diode Drn is connected to an emitter of the transistor Trn, and a collector of the transistor Trn is connected to the DC power line L2. An anode of the diode Dsn is connected to an emitter of the transistor Tsn, and a collector of the transistor Tsn is connected to the DC power line L2. An anode of the diode Dtn is connected to an emitter of the transistor Ttn, and a collector of the transistor Ttn is connected to the DC power line L2.
  • A collector of the transistor Trp is connected to a cathode of the diode Drn. In a similar manner, a collector of the transistor Tsp is connected to a cathode of the diode Dsn. A collector of the transistor Ttp is connected to a cathode of the diode Dtn.
  • Moreover, while Fig. 20 shows an example in which an anode of a diode is connected to an emitter of an IGBT in each element, a configuration in which a cathode of a diode is connected to a collector of an IGBT can also be adopted.
  • In addition, reverse blocking IGBTs (RB-IGBTs) can be used in place of the respective elements which are constituted by a diode and an IGBT.
  • The indirect matrix converter 20A comprises the clamp circuit 30A'. For example, the clamp circuit 30A' comprises an electrolytic capacitor as the clamp capacitor C. For example, the clamp circuit 30A' functions to absorb regenerative energy of a motor.
  • Switching control of the upper and lower arm-side switching elements of the current-type converter 100A is performed in a similar manner to the switching control performed by the power converter circuit 2C which has been described with reference to Fig. 11 and Fig. 12.
  • Fig. 21 shows an air conditioner 1G comprising an indirect matrix converter 20A' connected to the single-phase AC power supply E1. The indirect matrix converter 20A' comprises a current-type converter 100A', a clamp circuit 30A", and the voltage-type inverter 20.
  • The current-type converter 100A' is connected to the single-phase AC power supply E1 via input lines L1, Ln which respectively correspond to the L and N phases. In addition, the current-type converter 100A' is connected via the positive-side DC power line L1 and the negative-side DC power line L2 to the voltage-type inverter circuit 20 and the clamp circuit 30A". Moreover, the current-limiting circuit 50 is connected between the input line L1 and the positive-side DC power line L1.
  • Switching operations of the current-type converter 100A' are controlled by a control circuit 300A'.
  • In the present embodiment, the current-type converter 100A' comprises four sets of elements so as to correspond to upper and lower arms of the input lines L1, Ln from the single-phase AC power supply E1, with a diode and an IGBT connected in series in each element. The respective elements are an IGBT Tlp and a diode Dlp, an IGBT Tln and a diode Dln, an IGBT Tnp and a diode Dnp, and an IGBT Tnn and a diode Dnn.
  • An emitter of the transistor Tlp is connected to an anode of the diode Dlp, and a cathode of the diode Dlp is connected to the DC power line L1. An emitter of the transistor Tnp is connected to an anode of the diode Dnp, and a cathode of the diode Dnp is connected to the DC power line L1.
  • An anode of the diode Dln is connected to an emitter of the transistor Tln, and a collector of the transistor Tln is connected to the DC power line L2. An anode of the diode Dnn is connected to an emitter of the transistor Tnn, and a collector of the transistor Tnn is connected to the DC power line L2.
  • A collector of the transistor Tlp is connected to a cathode of the diode Dln. In a similar manner, a collector of the transistor Tnp is connected to a cathode of the diode Dnn.
  • Moreover, while Fig. 21 shows an example in which an anode of a diode is connected to an emitter of an IGBT in each element, a configuration in which a cathode of a diode is connected to a collector of an IGBT can also be adopted.
  • In addition, reverse blocking IGBTs (RB-IGBTs) can be used in place of the respective elements described above which are constituted by a diode and an IGBT.
  • The indirect matrix converter 20A' comprises the clamp circuit 30A". For example, the clamp circuit 30A" comprises an electrolytic capacitor as the clamp capacitor C. For example, the clamp circuit 30A" functions to absorb regenerative energy of a motor.
  • Switching control of the upper and lower arm-side switching elements of the current-type converter 100A' is performed in a similar manner to the switching control performed by the power converter circuit 2C' which has been described with reference to Fig. 14 and Fig. 15.
    • (4) In the first embodiment, at time t8 and time t7', the control unit 300C and the control unit 300C' place all upper and lower arm-side switching elements in a non-conductive state. However, since an object of the control unit 300C and the control unit 300C' is to stop accumulation of charges in the smoothing capacitor C when the motor M stops, the following control may be performed. Specifically, the control by the control unit 300C need only be control such that the current-limiting relay (84C) and only two pairs of upper and lower arm-side switching elements among the respective phases of R, S, T, the current-limiting relay (84C) and only all of the upper arm-side switching elements, or the current-limiting relay (84C) and only all of the lower arm-side switching elements are placed in a non-conductive state. The control by the control unit 300C' need only be control such that the current-limiting relay (84C) and only the pair of upper and lower arm-side switching elements of either the R phase or the N phase, the current-limiting relay (84C) and only all of the upper arm-side switching elements, or the current-limiting relay (84C) and only all of the lower arm-side switching elements are placed in a non-conductive state.
  • Moreover, the specific embodiments described above primarily include an invention configured as described below.
  • The power converter circuit according to the embodiments is a power converter circuit which is connected to a three-phase AC power supply (E3') via first to third input lines (Lr, Ls, Lt), and which is connected to a capacitor (C) via a positive-side DC power line (L1) and a negative-side DC power line (L2), and which is connected to at least one current-limiting circuit (50) that is provided between any one of the first to third input lines (Lr, Ls, Lt) and one of the positive-side DC power line (L1) and the negative-side DC power line (L2) and that includes an opening/closing switch (84C) and a current-limiting resistor (R1). The power converter circuit comprises: a switching element (Trp) that is provided on an arm on a side to which the current-limiting circuit (50) is connected of a phase to which the current-limiting circuit (50) is connected and that makes a current pathway between the first to third input lines (Lr, Ls, Lt) and the DC power lines (LI, L2) conductive in a conductive state; at least either switching elements (Tsp, Ttp) that are provided on arms on sides to which the current-limiting circuit is connected of two phases to which the current-limiting circuit is not connected and that make a current pathway from the first to third input lines (Lr, Ls, Lt) to the DC power lines (LI, L2) conductive in a conductive state, or switching elements (Trn, Tsn, Ttn) that are provided on an opposite-side arm in phase with the arm on which the switching element (Trp) is provided and both upper and lower arms of at least one phase among phases to which the current-limiting circuit is not connected and that make a current pathway between the DC power lines (LI, L2) and the first to third input lines (Lr, Ls, Lt) conductive in a conductive state; and control units (300D, 300E) which control switching of the switching elements (Trp, Tsp, Ttp, Trn, Tsn, Ttn) and control opening and closing of the opening/closing switch (84C). In the power converter circuit, the control units (300D, 300E) close the opening/closing switch (84C) until an inrush current becomes suppressible after start of energization of the power converter circuit, and control switching of each of the switching elements (Trp, Trn, Tsp, Tsn, Ttp, Ttn) so that the arm on the side to which the current-limiting circuit (50) is not connected of at least one phase among the phases to which the current-limiting circuit is not connected enters a conductive state and the remaining arms enter a non-conductive state.
  • According to this mode, the switching elements function as power switches. Therefore, a large electromagnetic relay as a power switch can be eliminated from an input unit of a converter circuit. As a result, the following effects (1) to (3) can be obtained. (1) Since there is no longer a risk of welding-induced stiction or degrading of the moving contact of the electromagnetic relay previously used as the power switch, the reliability of the converter circuit can be improved. (2) Electromagnetic noise generated when the moving contact opens and closes can be prevented from propagating to a low current circuit such as a control circuit of the power converter circuit and, in particular, to a low current circuit which shares a connection wire to a commercial power supply with the converter circuit and which is connected to a power supply branching from the connection wire. (3) A circuit board can be downsized.
  • The power converter circuit according to the embodiments is a power converter circuit which is connected to a single-phase AC power supply (E1) via two input lines (Ll, Ln) of an L phase and an N phase, and which is connected to a capacitor (C) via a positive-side DC power line (L1) and a negative-side DC power line (L2), and which is connected to at least one current-limiting circuit (50) that is provided between the input line (L1) of the L phase and the positive-side DC power line (L1) or between the input line (Ln) of the N phase and the negative-side DC power line (L2) and that includes an opening/closing switch (84C) and a current-limiting resistor (R1). The power converter circuit comprises: switching elements (Tlp) that are provided on an arm on a side to which the current-limiting circuit (50) is connected of a phase to which the current-limiting circuit (50) is connected and that make a current pathway between the input line (L1, Ln) of the L phase or the N phase and the DC power lines (L1, L2) conductive in a conductive state; switching elements (Tnp, Tln) that are provided at least on any one of an arm on a side to which the current-limiting circuit (50) is connected of a phase to which the current-limiting circuit (50) is not connected and an arm on a side to which the current-limiting circuit (50) is not connected of a phase to which the current-limiting circuit (50) is connected, that make a current pathway from the input line (L1, Ln) of the L phase or the N phase to the positive-side DC power line (L1) conductive in a conductive state when provided on an upper arm, and that make a current pathway from the negative-side DC power line (L2) to the input line (LI, Ln) of the L phase or the N phase conductive in a conductive state when provided on a lower arm; and control units (300A', 300B', 300C') that control switching of the switching elements (Tlp, Tln, Tnp) or four elements (Tlp, Tln, Tnp, Tnn) obtained by adding a switching element (Tnn) which makes the input line (Ln) of the N phase and the negative-side DC power line (L2) conductive to each other to the switching elements (Tlp, Tln, Tnp) and that control opening and closing of the opening/closing switch (84C). In the power converter circuit, the control units (300A', 300B', 300C') close the opening/closing switch (84C) until an inrush current becomes suppressible after start of energization of the power converter circuit, and control switching of each of the switching elements (Tlp, Tln, Tnp) so that the arm on the side to which the current-limiting circuit (50) is not connected of the phase to which the current-limiting circuit (50) is not connected enters a conductive state and the remaining arms enter a non-conductive state.
  • According to this mode, the switching elements function as power switches. Therefore, a large electromagnetic relay as a power switch can be eliminated from an input unit of a converter circuit. As a result, the following effects (1) to (3) can be obtained. (1) Since there is no longer a risk of welding-induced stiction or degrading of the moving contact of the electromagnetic relay previously used as the power switch, the reliability of the converter circuit can be improved. (2) Electromagnetic noise generated when the moving contact opens and closes can be prevented from propagating to a low current circuit such as a control circuit of the power converter circuit and, in particular, to a low current circuit which shares a connection wire to a commercial power supply with the converter circuit and which is connected to a power supply branching from the connection wire. (3) A circuit board can be downsized.
  • In the power converter circuit, favorably, the upper arm-side switching elements (Trp, Tsp, Ttp) are elements which are provided on all of the upper arms of the three phases and which are respectively capable of making a current pathway conductive in only one direction from the first to third input lines (Lr, Ls, Lt) to the positive-side DC power line (L1) when in a closed state. In this case, favorably, the lower arm-side switching elements (Trn, Tsn, Ttn) are elements which are provided on all of the lower arms of the three phases and which are respectively capable of making a current pathway conductive in only one direction from the negative-side DC power line (L2) to the first to third input lines (Lr, Ls, Lt) when in a closed state. In addition, favorably, the control unit (300C) closes the opening/closing switch (84C) until an inrush current becomes suppressible after start of energization of the power converter circuit, and places one pair among the three pairs of the upper arm-side switching elements (Trp, Tsp, Ttp) and the lower arm-side switching elements (Trn, Tsn, Ttn) connected to the same input lines in a conductive state and places the remaining two pairs in a non-conductive state.
  • This mode is suitable in a power converter circuit that is a so-called current-type converter or an indirect matrix converter which is capable of suppressing power supply harmonics.
  • In the power converter circuit, favorably, the upper arm-side switching elements (Trp, Tsp, Ttp) are elements which are provided on all of the upper arms of the three phases and which are respectively capable of making a current pathway conductive in only one direction from the first to third input lines (Lr, Ls, Lt) to the positive-side DC power line (L1) when in a closed state. In this case, favorably, the lower arm-side switching elements (Trn, Tsn, Ttn) are elements which are provided on all of the lower arms of the three phases and which are respectively capable of making a current pathway conductive in only one direction from the negative-side DC power line (L2) to the first to third input lines (Lr, Ls, Lt) when in a closed state. In addition, favorably, the control unit (300E) closes the opening/closing switch (84C) until an inrush current becomes suppressible after start of energization of the power converter circuit, and places at least switching elements (Tsn, Ttn) of an arm on a side to which the current-limiting circuit (50) is not connected among a pair of switching elements provided on upper and lower arms of one phase among phases to which the current-limiting circuit (50) is not connected in a conductive state and places the remaining switching elements in a non-conductive state.
  • This mode is suitable in a power converter circuit that is a so-called current-type converter or an indirect matrix converter which is capable of suppressing power supply harmonics.
  • In the power converter circuit, favorably, the switching elements (Tlp, Tln, Tnp, Tnn) are provided on all of the upper and lower arms. In this case, favorably, the control unit (300C') closes the opening/closing switch (84C) until an inrush current becomes suppressible after start of energization of the power converter circuit, and places the switching element (Tnn) on a side to which the current-limiting circuit (50) is not connected of a phase to which the current-limiting circuit (50) is not connected in a conductive state and places the remaining switching elements (Tlp, Tin, Tnp) in a non-conductive state.
  • This mode is suitable in a power converter circuit that is a so-called current-type converter or an indirect matrix converter which is capable of suppressing power supply harmonics.
  • In the power converter circuit, favorably, when stopping charging of the capacitor (C), the control units (300A, 300C, 300D, 300E) control switching of each of the switching elements (Trp, Trn, Tsp, Tsn, Ttp, Ttn) so that the upper and lower arms of at least two phases enter a non-conductive state.
  • According to this mode, since the switching elements function as power switches and stop supply of power from a commercial power supply, charging of the capacitor (C) can be stopped without having to use a large electromagnetic relay as a power switch.
  • In the power converter circuit, favorably, when stopping charging of the capacitor (C), the control units (300A', 300B', 300C') control switching of each of the switching elements (Tlp, Tln, Tnp, Tnn) so that the upper and lower arms of at least one phase enter a non-conductive state.
  • According to this mode, since the switching elements function as power switches and stop supply of power from a commercial power supply, charging of the capacitor (C) can be stopped without having to use a large electromagnetic relay as a power switch.
  • In the power converter circuit, favorably, when stopping charging of the capacitor (C), the control units (300C, 300E) control switching of each of the switching elements (Trp, Tsp, Ttp, Trn, Tsn, Ttn) so that at least either all of the upper arms or all of the lower arms enter a non-conductive state.
  • According to this mode, in a so-called current-type converter or in an indirect matrix converter which is capable of suppressing power supply harmonics, the switching elements can be made to function as power switches and charging of the capacitor (C) can be stopped without having to use a large electromagnetic relay as a power switch.
  • In the power converter circuit, favorably, when stopping charging of the capacitor (C), the control unit (300C') controls switching of each of the switching elements (Tip, Tnp, Tln, Tnn) so that at least either all of the upper arms or all of the lower arms enter a non-conductive state.
  • According to this mode, in a so-called current-type converter or in an indirect matrix converter which is capable of suppressing power supply harmonics, the switching elements can be made to function as power switches and charging of the capacitor (C) can be stopped without having to use a large electromagnetic relay as a power switch.
  • In the power converter circuit, favorably, the control units (300A, 300C) set a timing at which the opening/closing switch (84C) is closed until an inrush current becomes suppressible after start of energization as a timing at which a predetermined period of time in which an inrush current becomes suppressible has lapsed after the start of energization.
  • According to this mode, the control unit controls a period of time during which the opening/closing switch is closed by time measurement as a period of time in which a predetermined amount of time lapses. Therefore, the opening/closing switch can be kept closed in a reliable manner until a timing arrives which is determined in advance as a timing at which an inrush current becomes suppressible after the start of energization. Accordingly, an inrush current can be reliably suppressed.
  • In the power converter circuit, favorably, the opening/closing switch (84C) is any of a switching element capable of unidirectional energization or a circuit that combines an electromagnetic relay and a unidirectional energizing element.
  • According to this mode, a current can be sent unidirectionally from a power line to which the current-limiting circuit is connected to a DC power line. As a result, a stable current-limiting operation can be performed regardless of a phase relationship or a positive/negative relationship among respective phases of the power line and without allowing a current to flow in reverse from the power line side to the current-limiting circuit. When a switch is opened or closed by a switching element capable of unidirectional energization, there is no longer a risk of a decline in reliability of the power converter circuit due to welding-induced stiction or degradation of a moving contact and adverse effects of an electromagnetic noise created by contact bounce when the moving contact opens or closes can also be eliminated. In addition, when a switch is opened or closed by a circuit that combines an electromagnetic relay and a unidirectional energizing element, an interposition of the unidirectional energizing element reduces an electrical burden that acts on the moving contact of the electromagnetic relay. Accordingly, a decline in reliability of the power converter circuit due to welding-induced stiction or degradation of a moving contact can be reduced and adverse effects of the electromagnetic noise during opening and closing of the moving contact can also be reduced.
  • Favorably, the power converter circuit is a power converter circuit of a power supply circuit included in an air conditioner which executes a refrigeration cycle by circulating a refrigerant in a refrigerant circuit to which a compressor, a heat source-side heat exchanger, an expansion valve, and a utilization-side heat exchanger are connected through piping. In this case, favorably, when the control units (300A, 300C, 300D, 300E) receive a high pressure abnormality signal that is outputted when a high pressure sensor (400) which detects an abnormal rise of high pressure of the refrigeration cycle detects the abnormal rise, the control units (300A, 300C, 300D, 300E) control switching of each of the switching elements (Trp, Trn, Tsp, Tsn, Ttp, Ttn) so that the upper and lower arms of at least two phases enter a non-conductive state.
  • According to this mode, with a power converter circuit which is connected to a three-phase (three-wire system or four-wire system) power supply included in an air conditioner that comprises the high pressure switch and stops the refrigeration cycle when an abnormal rise of the high pressure of the refrigeration cycle occurs, an effect of promptly stopping supply of power can be obtained.
  • Favorably, the power converter circuit is a power converter circuit of a power supply circuit included in an air conditioner which executes a refrigeration cycle by circulating a refrigerant in a refrigerant circuit to which a compressor, a heat source-side heat exchanger, an expansion valve, and a utilization-side heat exchanger are connected through piping. In this case, favorably, when the control unit (300C) receives a high pressure abnormality signal that is outputted when a high pressure sensor (400) which detects an abnormal rise of high pressure of the refrigeration cycle detects the abnormal rise, the control unit (300C) controls switching of each of the switching elements (Trp, Tsp, Ttp, Trn, Tsn, Ttn) so that at least either all of the upper arms or all of the lower arms enter a non-conductive state.
  • According to this mode, with a power converter circuit which is connected to a three-phase (three-wire system or four-wire system) power supply included in an air conditioner that comprises the high pressure switch and stops the refrigeration cycle when an abnormal rise of the high pressure of the refrigeration cycle occurs, an effect of promptly stopping supply of power can be obtained.
  • Favorably, the power converter circuit is a power converter circuit of a power supply circuit included in an air conditioner which executes a refrigeration cycle by circulating a refrigerant in a refrigerant circuit to which a compressor, a heat source-side heat exchanger, an expansion valve, and a utilization-side heat exchanger are connected through piping. In this case, favorably, when the control units (300A', 300B', 300C') receive a high pressure abnormality signal that is outputted when a high pressure sensor (400) which detects an abnormal rise of high pressure of the refrigeration cycle detects the abnormal rise, the control units (300A', 300B', 300C') control switching of each of the switching elements (Tlp, Tln, Tnp, Tnn) so that the upper and lower arms of at least one phase enter a non-conductive state.
  • This mode is suitable for a converter circuit of a single-phase power supply circuit that is included in an air conditioner which comprises a high pressure switch and which stops the refrigeration cycle when an abnormal rise of high pressure of the refrigeration cycle occurs.
  • Favorably, the power converter circuit is a power converter circuit of a power supply circuit included in an air conditioner which executes a refrigeration cycle by circulating a refrigerant in a refrigerant circuit to which a compressor, a heat source-side heat exchanger, an expansion valve, and a utilization-side heat exchanger are connected through piping. In this case, favorably, when the control unit (300C') receives a high pressure abnormality signal that is outputted when a high pressure sensor (400) which detects an abnormal rise of high pressure of the refrigeration cycle detects the abnormal rise, the control unit (300C') controls switching of each of the switching elements (Tlp, Tnp, Tln, Tnn) so that at least either all of the upper arms or all of the lower arms enter a non-conductive state.
  • This mode is suitable for a converter circuit of a single-phase power supply circuit that is included in an air conditioner which comprises a high pressure switch and which stops the refrigeration cycle when an abnormal rise of high pressure of the refrigeration cycle occurs.
  • The air conditioner according to the present invention is an air conditioner comprising: a motor (M); and the power converter circuit (2A, 2A', 2B', 2C, 2C', 2D, 2E, 20A, 20A') with any one of the configurations above, wherein the power converter circuit (2A, 2A', 2B', 2C, 2C', 2D, 2E, 20A, 20A') includes a capacitor (C) connected to a converter circuit (10A, 10A', 10B', 10C, 10C', 10D, 10E, 100A, 100A') and an inverter circuit (20) connected between the capacitor (C) and the motor (M).
  • According to this mode, effects due to the power converter circuit can be obtained with an air conditioner comprising a motor and the power converter circuit that includes a capacitor connected to a converter circuit and an inverter circuit connected between the capacitor and the motor.
  • Explanation of Reference Numerals
    • E1 single-phase AC power supply
    • E3 three-phase AC power supply
    • 1A, 1A', 1B, 1B', 1C, 1C' air conditioner
    • M inverter motor
    • 2A, 2A', 2B', 2C, 2C', 20A, 20A' power converter circuit
    • Lr, Ls, Lt, Ln, Ll input line
    • L1 positive-side DC power line
    • L2 negative-side DC power line
    • C smoothing capacitor, clamp capacitor
    • 10A, 10A', 10B, 10B', 10C, 10C', 100A, 100A' converter circuit
    • Trp, Tsp, Ttp, Tnp, Tlp upper arm-side switching element
    • Trn, Tsn, Ttn, Tnn, Tln lower arm-side switching element
    • 100 converter gate drive IC
    • 20 inverter circuit
    • Tup, Tvp, Twp, Tun, Tvn, Twn switching element (inverter-side switching element)
    • 200 inverter gate drive IC
    • 300A, 300A', 300B, 300B', 300C, 300C' control unit
    • 400 high-pressure switch

Claims (7)

  1. A power converter circuit which is connected to a three-phase AC power supply (E3) via first to third input lines (Lr, Ls, Lt) and via a neutral line (Ln) including an opening/closing switch (84C) and a current-limiting resistor (R1) and which is connected to a capacitor (C) via a positive-side DC power line (L1) and a negative-side DC power line (L2), the power converter circuit comprising:
    - upper arm-side switching elements (Trp, Tsp, Ttp) which are provided on upper arms of at least two phases among upper arms of three phases and which makes a current pathway from the first to third input lines (Lr, Ls, Lt) to the positive-side DC power line(L1) conductive in a conductive state;
    - lower arm-side switching elements (Trn, Tsn, Ttn) which are provided on lower arms of the at least two phases among the three phases and which makes a current pathway from the negative-side DC power line (L2) to the first to third input lines (Lr, Ls, Lt) conductive in a conductive state;
    - control units (300C) which control switching of the upper arm-side switching elements (Trp, Tsp, Ttp) and the lower arm-side switching elements (Trn, Tsn, Ttn) and which control opening and closing of the opening/closing switch (84C), and
    - a shunt resistor (R2) which is provided between the lower arm-side switching elements (Trn, Tsn, Ttn) and the capacitor (C) on the negative-side DC power line (L2) and is used to measure a value of a current flowing into the capacitor (C),
    wherein
    - the control units (300C) closes the opening/closing switch (84C) until an inrush current becomes suppressible after start of energization of the power converter circuit and control switching of each of the switching elements (Trp, Trn, Tsp, Tsn, Ttp, Ttn) so that the upper and lower arms of one phase enter a conductive state and the remaining arms enter a non-conductive state
    - the upper arm-side switching elements (Trp, Tsp, Ttp) are elements which are provided on all of the upper arms of the three phases and which are respectively capable of making a current pathway conductive in only one direction from the first to third input lines (Lr, Ls, Lt) to the positive-side DC power line (L1) when in a closed state,
    - the lower arm-side switching elements (Trn, Tsn, Ttn) are elements which are provided on all of the lower arms of the three phases and which are respectively capable of making a current pathway conductive in only one direction from the negative-side DC power line (L2) to the first to third input lines (Lr, Ls, Lt) when in a closed state,
    - the control unit (300C) closes the opening/closing switch (84C) until the value of the current which is measured by using the shunt resistor (R2) falls to or below a predetermined value after start of energization of the power converter circuit, and places one pair among the three pairs of the upper arm-side switching elements (Trp, Tsp, Ttp) and the lower arm-side switching elements (Trn, Tsn, Ttn) connected to the same input lines in a conductive state and places the remaining two pairs in a non-conductive state, and when stopping charging of the capacitor (C), the control units (300C) control switching of each of the switching elements (Trp, Tsp, Ttp, Trn, Tsn, Ttn) so that at least either all of the upper arms or all of the lower arms enter a non-conductive state.
  2. The power converter circuit according to claim 1, wherein the opening/closing switch (84C) is any of a switching element capable of unidirectional energization or a circuit that combines an electromagnetic relay and a unidirectional energizing element.
  3. The power converter circuit according to any one of claims 1 or 2, wherein
    - the power converter circuit is a power converter circuit of a power supply circuit included in an air conditioner which executes a refrigeration cycle by circulating a refrigerant in a refrigerant circuit to which a compressor, a heat source-side heat exchanger, an expansion valve, and a utilization-side heat exchanger are connected through piping, and
    - when the control units (300C) receive a high pressure abnormality signal that is outputted when a high pressure sensor (400) which detects an abnormal rise of high pressure of the refrigeration cycle detects the abnormal rise, the control units (300C) control switching of each of the switching elements (Trp, Trn, Tsp, Tsn, Ttp, Ttn) so that the upper and lower arms of at least two phases enter a non-conductive state.
  4. The power converter circuit according to any one of claims 1 or 2, wherein
    - the power converter circuit is a power converter circuit of a power supply circuit included in an air conditioner which executes a refrigeration cycle by circulating a refrigerant in a refrigerant circuit to which a compressor, a heat source-side heat exchanger, an expansion valve, and a utilization-side heat exchanger are connected through piping, and
    - when the control unit (300C) receives a high pressure abnormality signal that is outputted when a high pressure sensor (400) which detects an abnormal rise of high pressure of the refrigeration cycle detects the abnormal rise, the control unit (300C) controls switching of each of the switching elements (Trp, Tsp, Ttp, Trn, Tsn, Ttn) so that at least either all of the upper arms or all of the lower arms enter a non-conductive state.
  5. The power converter circuit according to claims 2, wherein the power converter circuit is a power converter circuit of a power supply circuit included in an air conditioner which executes a refrigeration cycle by circulating a refrigerant in a refrigerant circuit to which a compressor, a heat source-side heat exchanger, an expansion valve, and a utilization-side heat exchanger are connected through piping, and when the control units (300C) receive a high pressure abnormality signal that is outputted when a high pressure sensor (400) which detects an abnormal rise of high pressure of the refrigeration cycle detects the abnormal rise, the control units (300C) control switching of each of the switching elements (Trp, Tsp, Ttp, Trn, Tsn, Ttn) so that the upper and lower arms of at least one phase enter a non-conductive state.
  6. The power converter circuit according to claim 2, wherein
    - the power converter circuit is a power converter circuit of a power supply circuit included in an air conditioner which executes a refrigeration cycle by circulating a refrigerant in a refrigerant circuit to which a compressor, a heat source-side heat exchanger, an expansion valve, and a utilization-side heat exchanger are connected through piping, and
    - when the control unit (300C) receives a high pressure abnormality signal that is outputted when a high pressure sensor (400) which detects an abnormal rise of high pressure of the refrigeration cycle detects the abnormal rise, the control unit (300C) controls switching of each of the switching elements (Trp, Tsp, Ttp, Trn, Tsn, Ttn) so that at least either all of the upper arms or all of the lower arms enter a non-conductive state.
  7. An air conditioner comprising:
    - a motor (M); and
    - the power converter circuit (2C) according to any one of claims 1 to 6,
    wherein
    - the power converter circuit (2C) includes:
    ∘ a converter circuit (10C);
    ∘ a capacitor (C) connected to the converter circuit (10C); and
    ∘ an inverter circuit (20) connected between the capacitor (C) and the motor (M).
EP15001646.7A 2011-05-02 2012-04-13 Power converter circuit and air conditioner Active EP2933914B1 (en)

Applications Claiming Priority (3)

Application Number Priority Date Filing Date Title
JP2011103230A JP5115636B2 (en) 2011-05-02 2011-05-02 Power conversion circuit and air conditioner
EP12779688.6A EP2698909B1 (en) 2011-05-02 2012-04-13 Power converter circuit, and air conditioner
PCT/JP2012/002573 WO2012150649A1 (en) 2011-05-02 2012-04-13 Power converter circuit, and air conditioner

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EP12779688.6A Division-Into EP2698909B1 (en) 2011-05-02 2012-04-13 Power converter circuit, and air conditioner

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EP2933914A2 EP2933914A2 (en) 2015-10-21
EP2933914A3 EP2933914A3 (en) 2016-04-06
EP2933914B1 true EP2933914B1 (en) 2018-11-14

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EP12779688.6A Active EP2698909B1 (en) 2011-05-02 2012-04-13 Power converter circuit, and air conditioner
EP15001646.7A Active EP2933914B1 (en) 2011-05-02 2012-04-13 Power converter circuit and air conditioner
EP15001645.9A Active EP2933913B1 (en) 2011-05-02 2012-04-13 Power converter circuit and air conditioner

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EP12779688.6A Active EP2698909B1 (en) 2011-05-02 2012-04-13 Power converter circuit, and air conditioner

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EP15001645.9A Active EP2933913B1 (en) 2011-05-02 2012-04-13 Power converter circuit and air conditioner

Country Status (5)

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EP (3) EP2698909B1 (en)
JP (1) JP5115636B2 (en)
CN (1) CN103534920B (en)
ES (3) ES2710717T3 (en)
WO (1) WO2012150649A1 (en)

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CN104917217B (en) * 2014-03-13 2018-06-26 珠海格力电器股份有限公司 Three-phase electric charging circuit and air conditioner
WO2016035982A1 (en) * 2014-09-05 2016-03-10 삼성전자주식회사 Inverter circuit, and air conditioner and refrigerator using same
JP2016195520A (en) * 2015-04-01 2016-11-17 三菱電機株式会社 Rush current protecting circuit, motor, and blowing device
JP6731829B2 (en) * 2016-10-19 2020-07-29 日立ジョンソンコントロールズ空調株式会社 Power converter and air conditioner
JP6485520B1 (en) * 2017-11-06 2019-03-20 ダイキン工業株式会社 Power converter and air conditioner
WO2019102529A1 (en) * 2017-11-21 2019-05-31 三菱電機株式会社 Air conditioner
JP6851331B2 (en) * 2018-01-11 2021-03-31 ダイキン工業株式会社 Power converter and air conditioner
JP6567223B1 (en) * 2018-01-24 2019-08-28 三菱電機株式会社 Motor control device
WO2020070850A1 (en) * 2018-10-04 2020-04-09 日立ジョンソンコントロールズ空調株式会社 Power conversion circuit and air conditioner
JP6884254B2 (en) * 2020-07-06 2021-06-09 日立ジョンソンコントロールズ空調株式会社 Power converter and air conditioner
NL2028254B1 (en) * 2021-05-19 2022-12-06 Prodrive Tech Innovation Services B V Electrical converter with overvoltage protection circuit
JP2024063335A (en) * 2022-10-26 2024-05-13 三星電子株式会社 Motor driving device

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Also Published As

Publication number Publication date
EP2698909A1 (en) 2014-02-19
WO2012150649A1 (en) 2012-11-08
EP2933914A3 (en) 2016-04-06
EP2698909B1 (en) 2016-09-21
ES2608694T3 (en) 2017-04-12
JP5115636B2 (en) 2013-01-09
CN103534920A (en) 2014-01-22
JP2012235632A (en) 2012-11-29
ES2674382T3 (en) 2018-06-29
EP2933914A2 (en) 2015-10-21
EP2698909A4 (en) 2014-12-10
CN103534920B (en) 2016-05-11
EP2933913B1 (en) 2018-03-21
ES2710717T3 (en) 2019-04-26
EP2933913A3 (en) 2016-04-06
EP2933913A2 (en) 2015-10-21

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